Rapid workflow system and method for image sequence depth enhancement

ABSTRACT

Movies to be colorized/depth enhanced (2D→3D) are broken into backgrounds/sets or motion/onscreen-action. Background and motion elements are combined into composite frame which becomes a visual reference database that includes data for all frame offsets used later for the computer controlled application of masks within a sequence of frames. Masks are applied to subsequent frames of motion objects based on various differentiating image processing methods, including automated mask fitting/reshaping. Colors/depths are automatically applied with masks throughout a scene from the composite background and to motion objects. Areas never exposed by motion or foreground objects may be partially or fully realistically drawn/rendered/applied to the occluded areas and applied throughout the images to generate artifact-free secondary viewpoints during 2D→3D conversion. Iterative workflow is eliminated for simple artifact correction through real-time manipulation of images to avoid re-rendering of images and associated delays of sending work product to other workgroups for correction.

This application is a continuation in part of U.S. Utility patent application Ser. No. 13/029,862, filed 17 Feb. 2011 now U.S. Pat. No. 8,385,684, which is a continuation in part of U.S. Utility patent application Ser. No. 12/976,970, filed 22 Dec. 2010 now U.S. Pat. No. 8,401,336, which is a continuation in part of U.S. Utility patent application Ser. No. 12/913,614, filed 27 Oct. 2010 now U.S. Pat. No. 8,396,328, which is a continuation in part of U.S. Utility patent application Ser. No. 12/542,498, filed 17 Aug. 2009, now U.S. Pat. No. 7,907,793, which is a continuation in part of U.S. Utility patent application Ser. No. 12/032,969, filed 18 Feb. 2008 now U.S. Pat. No. 7,577,312, which is a continuation of U.S. Utility patent application Ser. No. 11/324,815, issued as U.S. Pat. No. 7,333,670, filed 4 Jan. 2006, which is a divisional of U.S. Utility patent application Ser. No. 10/450,970, issued as U.S. Pat. No. 7,181,081, filed Jun. 18^(th), 2003 which is a national stage entry of Patent Cooperation Treaty Application Ser. No. PCT/US02/14192, filed May 6^(th), 2002, which claims the benefit of U.S. Provisional Patent Application 60/288,929, filed May 4^(th), 2001, the specifications of which are all hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

One or more embodiments of the invention are related to the field of image analysis and image enhancement and computer graphics processing of two-dimensional images into three-dimensional images. More particularly, but not by way of limitation, one or more embodiments of the invention enable a rapid workflow system and method for image sequence depth enhancement that enables high quality conversion of a large number of two-dimensional images into corresponding stereoscopic image pairs, or other three-dimensional viewing enabled images, such as an anaglyph through local modification of images that eliminates computationally expensive iterative ray tracing of light paths through each pixel in large format left and right eye images each time a minor change is made to depth or to fix artifacts.

2. Description of the Related Art

Known methods for the colorizing of black and white feature films involves the identification of gray scale regions within a picture followed by the application of a pre-selected color transform or lookup tables for the gray scale within each region defined by a masking operation covering the extent of each selected region and the subsequent application of said masked regions from one frame to many subsequent frames. The primary difference between U.S. Pat. No. 4,984,072, System And Method For Color Image Enhancement, and U.S. Pat. No. 3,705,762, Method For Converting Black-And-White Films To Color Films, is the manner by which the regions of interest (ROIs) are isolated and masked, how that information is transferred to subsequent frames and how that mask information is modified to conform with changes in the underlying image data. In the U.S. Pat. No. 4,984,072 system, the region is masked by an operator via a one-bit painted overlay and operator manipulated using a digital paintbrush method frame by frame to match the movement. In the U.S. Pat. No. 3,705,762 process, each region is outlined or rotoscoped by an operator using vector polygons, which are then adjusted frame by frame by the operator, to create animated masked ROIs. Various masking technologies are generally also utilized in the conversion of 2D movies to 3D movies.

In both systems described above, the color transform lookup tables and regions selected are applied and modified manually to each frame in succession to compensate for changes in the image data that the operator detects visually. All changes and movement of the underlying luminance gray scale is subjectively detected by the operator and the masks are sequentially corrected manually by the use of an interface device such as a mouse for moving or adjusting mask shapes to compensate for the detected movement. In all cases the underlying gray scale is a passive recipient of the mask containing pre-selected color transforms with all modifications of the mask under operator detection and modification. In these prior inventions the mask information does not contain any information specific to the underlying luminance gray scale and therefore no automatic position and shape correction of the mask to correspond with image feature displacement and distortion from one frame to another is possible.

Existing systems that are utilized to convert two-dimensional images to three-dimensional images may also require the creation of wire frame models for objects in images that define the 3D shape of the masked objects. The creation of wire frame models is a large undertaking in terms of labor. These systems also do not utilize the underlying luminance gray scale of objects in the images to automatically position and correct the shape of the masks of the objects to correspond with image feature displacement and distortion from one frame to another. Hence, great amounts of labor are required to manually shape and reshape masks for applying depth or Z-dimension data to the objects. Motion objects that move from frame to frame thus require a great deal of human intervention. In addition, there are no known solutions for enhancing two-dimensional images into three-dimensional images that utilize composite backgrounds of multiple images in a frame for spreading depth information to background and masked objects. This includes data from background objects whether or not pre-existing or generated for an occluded area where missing data exists, i.e., where motion objects never uncover the background. In other words, known systems gap fill using algorithms for inserting image data where none exists, which causes artifacts.

Current methods for converting movies from 2D to 3D that include computer-generated elements or effects, generally utilize only the final sequence of 2D images that make up the movie. This is the current method used for conversion of all movies from two-dimensional data to left and right image pairs for three-dimensional viewing. There are no known current methods that obtain and make use of metadata associated with the computer-generated elements for a movie to be converted. This is the case since studios that own the older 2D movies may not have retained intermediate data for a movie, i.e., the metadata associated with computer generated elements, since the amount of data in the past was so large that the studios would only retain the final movie data with rendered computer graphics elements and discard the metadata. For movies having associated metadata that has been retained, (i.e., intermediate data associated with the computer-generated elements such as mask, or alpha and/or depth information), use of this metadata would greatly speed the depth conversion process.

In addition, typical methods for converting movies from 2D to 3D in an industrial setting capable of handling the conversion of hundreds of thousands of frames of a movie with large amounts of labor or computing power, make use of an iterative workflow. The iterative workflow includes masking objects in each frame, adding depth and then rendering the frame into left and right viewpoints forming an anaglyph image or a left and right image pair. If there are errors in the edges of the masked objects for example, then the typical workflow involves an “iteration”, i.e., sending the frames back to the workgroup responsible for masking the objects, (which can be in a country with cheap unskilled labor half way around the world), after which the masks are sent to the workgroup responsible for rendering the images, (again potentially in another country), wherein rendering is accomplished by ray tracing the path of light through each pixel in left and right images to simulate the light effects the path of light interacts with and for example bounces off of or through, which is computationally extremely expensive. After ray tracing, the rendered image pair is sent back to the quality assurance group. It is not uncommon in this workflow environment for many iterations of a complicated frame to take place. This is known as “throw it over the fence” workflow since different workgroups work independently to minimize their current work load and not as a team with overall efficiency in mind. With hundreds of thousands of frames in a movie, the amount of time that it takes to iterate back through frames containing artifacts can become high, causing delays in the overall project. Even if the re-rendering process takes place locally, the amount of time to re-render or ray-trace all of the images of a scene can cause significant processing and hence delays on the order of at least hours. Elimination of iterations such as this would provide a huge savings in wall-time, or end-to-end time that a conversion project takes, thereby increasing profits and minimizing the workforce needed to implement the workflow.

Hence there is a need for a rapid workflow system and method for image sequence depth enhancement.

BRIEF SUMMARY OF THE INVENTION

Embodiments of the invention generally classify scenes to be colorized and/or converted from two-dimensional to three-dimensional into movies into two separate categories. Scenes generally include two or more images in time sequence for example. The two categories include background elements (i.e. sets and foreground elements that are stationary) or motion elements (e.g., actors, automobiles, etc.) that move throughout the scene. These background elements and motion elements are treated separately in embodiments of the invention similar to the manner in which traditional animation is produced. In addition, many movies now include computer-generated elements (also known as computer graphics or CG, or also as computer-generated imagery or CGI) that include objects that do not exist in reality, such as robots or spaceships for example, or which are added as effects to movies, for example dust, fog, clouds, etc. Computer-generated elements may include background elements, or motion elements.

Motion Elements: The motion elements are displayed as a series of sequential tiled frame sets or thumbnail images complete with background elements. The motion elements are masked in a key frame using a multitude of operator interface tools common to paint systems as well as unique tools such as relative bimodal thresholding in which masks are applied selectively to contiguous light or dark areas bifurcated by a cursor brush. After the key frame is fully designed and masked, the mask information from the key frame is then applied to all frames in the display-using mask fitting techniques that include:

1. Automatic mask fitting using Fast Fourier Transform and Gradient Decent Calculations based on luminance and pattern matching which references the same masked area of the key frame followed by all prior subsequent frames in succession. Since the computer system implementing embodiments of the invention can reshape at least the outlines of masks from frame to frame, large amounts of labor can be saved from this process that traditionally has been done by hand. In 2D to 3D conversion projects, sub-masks can be adjusted manually within a region of interest when a human recognizable object rotates for example, and this process can be “tweened” such that the computer system automatically adjusts sub-masks from frame to frame between key frames to save additional labor.

2. Bezier curve animation with edge detection as an automatic animation guide

3. Polygon animation with edge detection as an automatic animation guide

In one or more embodiments of the invention, computer-generated elements are imported using RGBAZ files that include an optional alpha mask and/or depths on a pixel-by-pixel, or sub-pixel-by-sub-pixel basis for a computer-generated element. Examples of this type of file include the EXR file format. Any other file format capable of importing depth and/or alpha information is in keeping with the spirit of the invention. Embodiments of the invention import any type of file associated with a computer-generated element to provide instant depth values for a portion of an image associated with a computer-generated element. In this manner, no mask fitting or reshaping is required for any of the computer-generated elements from frame to frame since the alpha and depth on a pixel-by-pixel or sub-pixel-by-sub-pixel basis already exists, or is otherwise imported or obtained for the computer-generated element. For complicated movies with large amounts of computer-generated elements, the import and use of alpha and depth for computer-generated elements makes the conversion of a two-dimensional image to a pair of images for right and left eye viewing economically viable. One or more embodiments of the invention allow for the background elements and motion elements to have depths associated with them or otherwise set or adjusted, so that all objects other than computer-generated objects are artistically depth adjusted. In addition, embodiments of the invention allow for the translation, scaling or normalization of the depths for example imported from an RGBAZ file that are associated with computer-generated objects so as to maintain the relative integrity of depth for all of the elements in a frame or sequence of frames. In addition, any other metadata such as character mattes or alphas or other masks that exist for elements of the images that make up a movie can also be imported and utilized to improve the operated-defined masks used for conversion. On format of a file that may be imported to obtain metadata for photographic elements in a scene includes the RGBA file format. By layering different objects from deepest to closest, i.e., “stacking” and applying any alpha or mask of each element, and translating the closest objects the most horizontally for left and right images, a final pair of depth enhanced images is thus created based on the input image and any computer-generated element metadata.

In another embodiment of this invention, these background elements and motion elements are combined separately into single frame representations of multiple frames, as tiled frame sets or as a single frame composite of all elements (i.e., including both motion and backgrounds/foregrounds) that then becomes a visual reference database for the computer controlled application of masks within a sequence composed of a multiplicity of frames. Each pixel address within the reference visual database corresponds to mask/lookup table address within the digital frame and X, Y, Z location of subsequent “raw” frames that were used to create the reference visual database. Masks are applied to subsequent frames based on various differentiating image processing methods such as edge detection combined with pattern recognition and other sub-mask analysis, aided by operator segmented regions of interest from reference objects or frames, and operator directed detection of subsequent regions corresponding to the original region of interest. In this manner, the gray scale actively determines the location and shape of each mask (and corresponding color lookup from frame to frame for colorization projects or depth information for two-dimensional to three-dimensional conversion projects) that is applied in a keying fashion within predetermined and operator-controlled regions of interest.

Camera Pan Background and Static Foreground Elements: Stationary foreground and background elements in a plurality of sequential images comprising a camera pan are combined and fitted together using a series of phase correlation, image fitting and focal length estimation techniques to create a composite single frame that represents the series of images used in its construction. During the process of this construction the motion elements are removed through operator adjusted global placement of overlapping sequential frames.

For colorization projects, the single background image representing the series of camera pan images is color designed using multiple color transform look up tables limited only by the number of pixels in the display. This allows the designer to include as much detail as desired including air brushing of mask information and other mask application techniques that provide maximum creative expression. For depth conversion projects, (i.e., two-dimensional to three-dimensional movie conversion for example), the single background image representing the series of camera pan images may be utilized to set depths of the various items in the background. Once the background color/depth design is completed the mask information is transferred automatically to all the frames that were used to create the single composited image. In this manner, color or depth is performed once per multiple images and/or scene instead of once per frame, with color/depth information automatically spread to individual frames via embodiments of the invention. Masks from colorization projects may be combined or grouped for depth conversion projects since the colorization masks may contain more sub-areas than a depth conversion mask. For example, for a coloration project, a person's face may have several masks applied to areas such as lips, eyes, hair, while a depth conversion project may only require an outline of the person's head or an outline of a person's nose, or a few geometric shape sub-masks to which to apply depth. Masks from a colorization project can be utilized as a starting point for a depth conversion project since defining the outlines of human recognizable objects by itself is time consuming and can be utilized to start the depth conversion masking process to save time. Any computer-generated elements at the background level may be applied to the single background image.

In one or more embodiments of the invention, image offset information relative to each frame is registered in a text file during the creation of the single composite image representing the pan and used to apply the single composite mask to all the frames used to create the composite image.

Since the foreground moving elements have been masked separately prior to the application of the background mask, the background mask information is applied wherever there is no pre-existing mask information.

Static Camera Scenes With and Without Film Weave, Minor Camera Following and Camera Drift: In scenes where there is minor camera movement or film weave resulting from the sprocket transfer from 35 mm or 16 mm film to digital format, the motion objects are first fully masked using the techniques listed above. All frames in the scene are then processed automatically to create a single image that represents both the static foreground elements and background elements, eliminating all masked moving objects where they both occlude and expose the background.

Wherever the masked moving object exposes the background or foreground, the instance of background and foreground previously occluded is copied into the single image with priority and proper offsets to compensate for camera movement. The offset information is included in a text file associated with each single representation of the background so that the resulting mask information can be applied to each frame in the scene with proper mask offsets.

The single background image representing the series of static camera frames is color designed using multiple color transform look up tables limited only by the number of pixels in the display. Where the motion elements occlude the background elements continuously within the series of sequential frames they are seen as black figure that are ignored and masked over. The black objects are ignored in colorization-only projects during the masking operation because the resulting background mask is later applied to all frames used to create the single representation of the background only where there is no pre-existing mask. If background information is created for areas that are never exposed, then this data is treated as any other background data that is spread through a series of images based on the composite background. This allows for minimization of artifacts or artifact-free two-dimensional to three-dimensional conversion since there is never any need to stretch objects or extend pixels as for missing data, since image data that has been generated to be believable to the human observer is generated for and then taken from the occluded areas when needed during the depth conversion process. Hence for motion elements and computer-generated elements, realistic looking data can be utilized for areas behind these elements when none exists. This allows the designer to include as much detail as desired including air brushing of mask information and other mask application techniques that provide maximum creative expression. Once the background color design is completed the mask information is transferred automatically to all the frames that were used to create the single composited image. For depth projects, the distance from the camera to each item in the composite frame is automatically transferred to all the frames that were used to create the single composited image. By shifting masked background objects horizontally more or less, their perceived depth is thus set in a secondary viewpoint frame that corresponds to each frame in the scene. This horizontal shifting may utilize data generated by an artist for the occluded or alternatively, areas where no image data exists yet for a second viewpoint may be marked in one or more embodiments of the invention using a user defined color that allows for the creation missing data to ensure that no artifacts occur during the two-dimension to three-dimension conversion process. Any technique known may be utilized in embodiments of the invention to cover areas in the background where unknown data exists, i.e., (as displayed in some color that shows where the missing data exists) that may not be borrowed from another scene/frame for example by having artists create complete backgrounds or smaller occluded areas with artist drawn objects. After assigning depths to objects in the composite background, or by importing depths associated with computer-generated elements at the background depth, a second viewpoint image may be created for each image in a scene in order to produce a stereoscopic view of the movie, for example a left eye view where the original frames in the scene are assigned to the right eye viewpoint, for example by translating foreground objects horizontally for the second viewpoint, or alternatively by translating foreground objects horizontally left and right to create two viewpoints offset from the original viewpoint.

Embodiments of the invention enable local processing and eliminates iterative ray tracing. For example, embodiments of the invention enable local masking of desired regions to be depth enhanced, realistic gap fill to fill in areas the are not visible in any other frames in a scene once an object is translated left and right to add depth, including gap fill with grain and blur to emulate existing portions of an image that are not occluded. Embodiments of the invention also enable sophisticated depth dilation and distortion, and in addition enable the detection of gaps in translation maps. The system also enables real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove artifacts and to minimize or eliminate iterative workflow paths back through different workgroups by generating translation files that can be utilized as portable pixel-wise editing files. Great amounts of time are saved by eliminating ray tracing, and enabling adjustments to be made local to a work group. Embodiments of the system thus greatly aid the artist in the enhancement of images to include depth by providing realistic depth modifications to minimize manual manipulation of images. For example, a mask group takes source images and creates masks for items, areas or human recognizable objects in each frame of a sequence of images that make up a movie. The depth augmentation group applies depths, and for example shapes, to the masks created by the mask group. When rendering an image pair, left and right viewpoint images and left and right translation files may be generated by one or more embodiments of the invention. The left and right viewpoint images allow 3D viewing of the original 2D image. The translation files specify the pixel offsets for each source pixel in the original 2D image, for example in the form of UV or U maps. These files are generally related to an alpha mask for each layer, for example a layer for an actress, a layer for a door, a layer for a background, etc. These translation files, or maps are passed from the depth augmentation group that renders 3D images, to the quality assurance workgroup. This allows the quality assurance workgroup (or other workgroup such as the depth augmentation group) to perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove artifacts such as masking errors without delays associated with processing time/re-rendering and/or iterative workflow that requires such re-rendering or sending the masks back to the mask group for rework, wherein the mask group may be in a third world country with unskilled labor on the other side of the globe. In addition, when rendering the left and right images, i.e., 3D images, the Z depth of regions within the image, such as actors for example, may also be passed along with the alpha mask to the quality assurance group, who may then adjust depth as well without re-rendering with the original rendering software. This may be performed for example with generated missing background data from any layer so as to allow “downstream” real-time editing without re-rendering or ray-tracing for example. Quality assurance may give feedback to the masking group or depth augmentation group for individuals so that these individuals may be instructed to produce work product as desired for the given project, without waiting for, or requiring the upstream groups to rework anything for the current project. This allows for feedback yet eliminates iterative delays involved with sending work product back for rework and the associated delay for waiting for the reworked work product. Elimination of iterations such as this provide a huge savings in wall-time, or end-to-end time that a conversion project takes, thereby increasing profits and minimizing the workforce needed to implement the workflow.

BRIEF DESCRIPTION OF THE DRAWINGS

The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.

FIG. 1 shows a plurality of feature film or television film frames representing a scene or cut in which there is a single instance or perceptive of a background.

FIG. 2 shows an isolated background processed scene from the plurality of frames shown in FIG. 1 in which all motion elements are removed using various subtraction and differencing techniques. The single background image is then used to create a background mask overlay representing designer selected color lookup tables in which dynamic pixel colors automatically compensate or adjust for moving shadows and other changes in luminance.

FIG. 3 shows a representative sample of each motion object (M-Object) in the scene receives a mask overlay that represents designer selected color lookup tables in which dynamic pixel colors automatically compensate or adjust for moving shadows and other changes in luminance as the M-Object moves within the scene.

FIG. 4 shows all mask elements of the scene are then rendered to create a fully colored frame in which M-Object masks are applied to each appropriate frame in the scene followed by the background mask, which is applied only where there is no pre-existing mask in a Boolean manner.

FIGS. 5A and 5B show a series of sequential frames loaded into display memory in which one frame is fully masked with the background (key frame) and ready for mask propagation to the subsequent frames via automatic mask fitting methods.

FIGS. 6A and 6B show the child window displaying an enlarged and scalable single image of the series of sequential images in display memory. The Child window enables the operator to manipulate masks interactively on a single frame or in multiple frames during real time or slowed motion.

FIGS. 7A and 7B shows a single mask (flesh) is propagated automatically to all frames in the display memory.

FIG. 8 shows all masks associated with the motion object are propagated to all sequential frames in display memory.

FIG. 9A shows a picture of a face.

FIG. 9B shows a close up of the face in FIG. 9A wherein the “small dark” pixels shown in FIG. 9B are used to calculate a weighed index using bilinear interpolation.

FIGS. 10A-D show searching for a Best Fit on the Error Surface: An error surface calculation in the Gradient Descent Search method involves calculating mean squared differences of pixels in the square fit box centered on reference image pixel (x0, y0), between the reference image frame and the corresponding (offset) location (x, y) on the search image frame.

FIGS. 11A-C show a second search box derived from a descent down the error surface gradient (evaluated separately), for which the evaluated error function is reduced, possibly minimized, with respect to the original reference box (evident from visual comparison of the boxes with the reference box in FIGS. 10A, B, C and D).

FIG. 12 depicts the gradient component evaluation. The error surface gradient is calculated as per definition of the gradient. Vertical and horizontal error deviations are evaluated at four positions near the search box center position, and combined to provide an estimate of the error gradient for that position. 12.

FIG. 13 shows a propagated mask in the first sequential instance where there is little discrepancy between the underlying image data and the mask data. The dress mask and hand mask can be clearly seen to be off relative to the image data.

FIG. 14 shows that by using the automatic mask fitting routine, the mask data adjusts to the image data by referencing the underlying image data in the preceding image.

FIG. 15 shows the mask data in later images within the sequence show marked discrepancy relative to the underlying image data. Eye makeup, lipstick, blush, hair, face, dress and hand image data are all displaced relative to the mask data.

FIG. 16 shows that the mask data is adjusted automatically based on the underlying image data from the previous mask and underlying image data.

FIG. 17 shows the mask data from FIG. 16 is shown with appropriate color transforms after whole frame automatic mask fitting. The mask data is adjusted to fit the underlying luminance pattern based on data from the previous frame or from the initial key frame.

FIG. 18 shows polygons that are used to outline a region of interest for masking in frame one. The square polygon points snap to the edges of the object of interest. Using a Bezier curve the Bezier points snap to the object of interest and the control points/curves shape to the edges.

FIG. 19 shows the entire polygon or Bezier curve is carried to a selected last frame in the display memory where the operator adjusts the polygon points or Bezier points and curves using the snap function which automatically snaps the points and curves to the edges of the object of interest.

FIG. 20 shows that if there is a marked discrepancy between the points and curves in frames between the two frames where there was an operator interactive adjustment, the operator will further adjust a frame in the middle of the plurality of frames where there is maximum error of fit.

FIG. 21 shows that when it is determined that the polygons or Bezier curves are correctly animating between the two adjusted frames, the appropriate masks are applied to all frames.

FIG. 22 shows the resulting masks from a polygon or Bezier animation with automatic point and curve snap to edges. The brown masks are the color transforms and the green masks are the arbitrary color masks.

FIG. 23 shows an example of two pass blending: The objective in two-pass blending is to eliminate moving objects from the final blended mosaic. This can be done by first blending the frames so the moving object is completely removed from the left side of the background mosaic. As shown in FIG. 23, the character can is removed from the scene, but can still be seen in the right side of the background mosaic.

FIG. 24 shows the second pass blend. A second background mosaic is then generated, where the blend position and width is used so that the moving object is removed from the right side of the final background mosaic. As shown in FIG. 24, the character can is removed from the scene, but can still be seen the left side of the background mosaic. In the second pass blend as shown in FIG. 24, the moving character is shown on the left.

FIG. 25 shows the final background corresponding to FIGS. 23-24. The two-passes are blended together to generate the final blended background mosaic with the moving object removed from the scene. As shown in FIG. 25, the final blended background with moving character is removed.

FIG. 26 shows an edit frame pair window.

FIG. 27 shows sequential frames representing a camera pan that are loaded into memory. The motion object (butler moving left to the door) has been masked with a series of color transform information leaving the background black and white with no masks or color transform information applied.

FIG. 28 shows six representative sequential frames of the pan above are displayed for clarity.

FIG. 29 shows the composite or montage image of the entire camera pan that was built using phase correlation techniques. The motion object (butler) included as a transparency for reference by keeping the first and last frame and averaging the phase correlation in two directions. The single montage representation of the pan is color designed using the same color transform masking techniques as used for the foreground object.

FIG. 30 shows that the sequence of frames in the camera pan after the background mask color transforms the montage has been applied to each frame used to create the montage. The mask is applied where there is no pre-existing mask thus retaining the motion object mask and color transform information while applying the background information with appropriate offsets.

FIG. 31 shows a selected sequence of frames in the pan for clarity after the color background masks have been automatically applied to the frames where there is no pre-existing masks.

FIG. 32 shows a sequence of frames in which all moving objects (actors) are masked with separate color transforms.

FIG. 33 shows a sequence of selected frames for clarity prior to background mask information. All motion elements have been fully masked using the automatic mask-fitting algorithm.

FIG. 34 shows the stationary background and foreground information minus the previously masked moving objects. In this case, the single representation of the complete background has been masked with color transforms in a manner similar to the motion objects. Note that outlines of removed foreground objects appear truncated and unrecognizable due to their motion across the input frame sequence interval, i.e., the black objects in the frame represent areas in which the motion objects (actors) never expose the background and foreground. The black objects are ignored during the masking operation in colorization-only projects because the resulting background mask is later applied to all frames used to create the single representation of the background only where there is no pre-existing mask. In depth conversion projects the missing data area may be displayed so that image data may be obtained/generated for the missing data area so as to provide visually believable image data when translating foreground objects horizontally to generate a second viewpoint.

FIG. 35 shows the sequential frames in the static camera scene cut after the background mask information has been applied to each frame with appropriate offsets and where there is no pre-existing mask information.

FIG. 36 shows a representative sample of frames from the static camera scene cut after the background information has been applied with appropriate offsets and where there is no pre-existing mask information.

FIGS. 37A-C show embodiments of the Mask Fitting functions, including calculate fit grid and interpolate mask on fit grid.

FIGS. 38A-B show embodiments of the extract background functions.

FIGS. 39A-C show embodiments of the snap point functions.

FIGS. 40A-C show embodiments of the bimodal threshold masking functions, wherein FIG. 40C corresponds to step 2.1 in FIG. 40A, namely “Create Image of Light/Dark Cursor Shape” and FIG. 40B corresponds to step 2.2 in FIG. 40A, namely “Apply Light/Dark shape to mask”.

FIGS. 41A-B show embodiments of the calculate fit value functions.

FIG. 42 shows two image frames that are separated in time by several frames, of a person levitating a crystal ball wherein the various objects in the image frames are to be converted from two-dimensional objects to three-dimensional objects.

FIG. 43 shows the masking of the first object in the first image frame that is to be converted from a two-dimensional image to a three-dimensional image.

FIG. 44 shows the masking of the second object in the first image frame.

FIG. 45 shows the two masks in color in the first image frame allowing for the portions associated with the masks to be viewed.

FIG. 46 shows the masking of the third object in the first image frame.

FIG. 47 shows the three masks in color in the first image frame allowing for the portions associated with the masks to be viewed.

FIG. 48 shows the masking of the fourth object in the first image frame.

FIG. 49 shows the masking of the fifth object in the first image frame.

FIG. 50 shows a control panel for the creation of three-dimensional images, including the association of layers and three-dimensional objects to masks within an image frame, specifically showing the creation of a Plane layer for the sleeve of the person in the image.

FIG. 51 shows a three-dimensional view of the various masks shown in FIGS. 43-49, wherein the mask associated with the sleeve of the person is shown as a Plane layer that is rotated toward the left and right viewpoints on the right of the page.

FIG. 52 shows a slightly rotated view of FIG. 51.

FIG. 53 shows a slightly rotated view of FIG. 51.

FIG. 54 shows a control panel specifically showing the creation of a sphere object for the crystal ball in front of the person in the image.

FIG. 55 shows the application of the sphere object to the flat mask of the crystal ball, that is shown within the sphere and as projected to the front and back of the sphere to show the depth assigned to the crystal ball.

FIG. 56 shows a top view of the three-dimensional representation of the first image frame showing the Z-dimension assigned to the crystal ball shows that the crystal ball is in front of the person in the scene.

FIG. 57 shows that the sleeve plane rotating in the X-axis to make the sleeve appear to be coming out of the image more.

FIG. 58 shows a control panel specifically showing the creation of a Head object for application to the person's face in the image, i.e., to give the person's face realistic depth without requiring a wire model for example.

FIG. 59 shows the Head object in the three-dimensional view, too large and not aligned with the actual person's head.

FIG. 60 shows the Head object in the three-dimensional view, resized to fit the person's face and aligned, e.g., translated to the position of the actual person's head.

FIG. 61 shows the Head object in the three-dimensional view, with the Y-axis rotation shown by the circle and Y-axis originating from the person's head thus allowing for the correct rotation of the Head object to correspond to the orientation of the person's face.

FIG. 62 shows the Head object also rotated slightly clockwise, about the Z-axis to correspond to the person's slightly tilted head.

FIG. 63 shows the propagation of the masks into the second and final image frame.

FIG. 64 shows the original position of the mask corresponding to the person's hand.

FIG. 65 shows the reshaping of the mask, that can be performed automatically and/or manually, wherein any intermediate frames get the tweened depth information between the first image frame masks and the second image frame masks.

FIG. 66 shows the missing information for the left viewpoint as highlighted in color on the left side of the masked objects in the lower image when the foreground object, here a crystal ball is translated to the right.

FIG. 67 shows the missing information for the right viewpoint as highlighted in color on the right side of the masked objects in the lower image when the foreground object, here a crystal ball is translated to the left.

FIG. 68 shows an anaglyph of the final depth enhanced first image frame viewable with Red/Blue 3-D glasses.

FIG. 69 shows an anaglyph of the final depth enhanced second and last image frame viewable with Red/Blue 3-D glasses, note rotation of person's head, movement of person's hand and movement of crystal ball.

FIG. 70 shows the right side of the crystal ball with fill mode “smear”, wherein the pixels with missing information for the left viewpoint, i.e., on the right side of the crystal ball are taken from the right edge of the missing image pixels and “smeared” horizontally to cover the missing information.

FIG. 71 shows a mask or alpha plane, for an actor's upper torso and head (and transparent wings). The mask may include opaque areas shown as black and transparent areas that are shown as grey areas.

FIG. 72 shows an occluded area, that corresponds to the actor of FIG. 71, and that shows an area of the background that is never exposed in any frame in a scene. This may be a composite background for example.

FIG. 73 shows the occluded area artistically rendered to generate a complete and realistic background for use in two-dimensional to three-dimensional conversion, so as to enable an artifact-free conversion.

FIG. 73A shows the occluded area partially drawn or otherwise rendered to generate just enough of a realistic looking background for use in minimizing artifacts two-dimensional to three-dimensional conversion.

FIG. 74 shows a light area of the shoulder portion on the right side of FIG. 71 that represents a gap where stretching (as is also shown in FIG. 70) would be used when shifting the foreground object to the left to create a right viewpoint. The dark portion of the figure is taken from the background where data is available in at least one frame of a scene.

FIG. 75 shows an example of the stretching of pixels, i.e., smearing, corresponding to the light area in FIG. 74 without the use of a generated background, i.e., if no background data is available for an area that is occluded in all frames of a scene.

FIG. 76 shows a result of a right viewpoint without artifacts on the edge of the shoulder of the person wherein the dark area includes pixels available in one or more frames of a scene, and generated data for always-occluded areas of a scene.

FIG. 77 shows an example of a computer-generated element, here a robot, which is modeled in three-dimensional space and projected as a two-dimensional image. If metadata such as alpha, mask, depth or any combination thereof exists, the metadata can be utilized to speed the conversion process from two-dimensional image to a pair of two-dimensional images for left and right eye for three-dimensional viewing.

FIG. 78 shows an original image separated into a background and foreground elements, (mountain and sky in the background and soldiers in the bottom left also see FIG. 79) along with the imported color and depth of the computer-generated element, i.e., the robot with depth automatically set via the imported depth metadata. As shown in the background, any area that is covered for the scene can be artistically rendered for example to provide believable missing data, as is shown in FIG. 73 based on the missing data of FIG. 73A, which results in artifact free edges as shown in FIG. 76 for example.

FIG. 79 shows masks associated with the photograph of soldiers in the foreground to apply depth to the various portions of the soldiers that lie in depth in front of the computer-generated element, i.e., the robot. The dashed lines horizontally extending from the mask areas show horizontal translation of the foreground objects takes place and where imported metadata can be utilized to accurately auto-correct over-painting of depth or color on the masked objects when metadata exists for the other elements of a movie. For example, when an alpha exists for the objects that occur in front of the computer-generated elements. One type of file that can be utilized to obtain mask edge data is a file with alpha file and/or mask data such as an RGBA file.

FIG. 80 shows an imported alpha layer which can also be utilized as a mask layer to limit the operator defined, and potentially less accurate masks used for applying depth to the edges of the three soldiers A, B and C. In addition, a computer-generated element for dust can be inserted into the scene along the line annotated as “DUST”, to augment the reality of the scene.

FIG. 81 shows the result of using the operator-defined masks without adjustment when overlaying a motion element such as the soldier on the computer-generated element such as the robot. Through use of the alpha metadata of FIG. 80 applied to the operated-defined mask edges of FIG. 79, artifact free edges on the overlapping areas is thus enabled.

FIG. 82 shows a source image to be depth enhanced and provided along with left and right translation files and alpha masks so that downstream workgroups may perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove and/or or adjust depths without iterative workflow paths back to the original workgroups.

FIG. 83 shows masks generated by the mask workgroup for the application of depth by the depth augmentation group, wherein the masks are associated with objects, such as for example human recognizable objects in the source image of FIG. 82.

FIG. 84 shows areas where depth is applied generally as darker for nearer objects and lighter for objects that are further away.

FIG. 85A shows a left UV map containing translations or offsets in the horizontal direction for each source pixel.

FIG. 85B shows a right UV map containing translations or offsets in the horizontal direction for each source pixel.

FIG. 85C shows a black value shifted portion of the left UV map of FIG. 85A to show the subtle contents therein.

FIG. 85D shows a black value shifted portion of the right UV map of FIG. 85B to show the subtle contents therein.

FIG. 86A shows a left U map containing translations or offsets in the horizontal direction for each source pixel.

FIG. 86B shows a right U map containing translations or offsets in the horizontal direction for each source pixel.

FIG. 86C shows a black value shifted portion of the left U map of FIG. 86A to show the subtle contents therein.

FIG. 86D shows a black value shifted portion of the right U map of FIG. 86B to show the subtle contents therein.

FIG. 87 shows known uses for UV maps, wherein a three-dimensional model is unfolded so that an image in UV space can be painted onto the 3D model using the UV map.

FIG. 88 shows a disparity map showing the areas where the difference between the left and right translation maps is the largest.

FIG. 89 shows a left eye rendering of the source image of FIG. 82.

FIG. 90 shows a right eye rendering of the source image of FIG. 82.

FIG. 91 shows an anaglyph of the images of FIG. 89 and FIG. 90 for use with Red/Blue glasses.

FIG. 92 shows an image that has been masked and is in the process of depth enhancement for the various layers.

FIG. 93 shows a UV map overlaid onto an alpha mask associated with the actress shown in FIG. 92 which sets the translation offsets in the resulting left and right UV maps based on the depth settings of the various pixels in the alpha mask.

FIG. 94 shows a workspace generated for a second depth enhancement program, or compositing program such as NUKE®, i.e., generated for the various layers shown in FIG. 92, i.e., left and right UV translation maps for each of the alphas wherein the workspace allows for quality assurance personnel (or other work groups) to perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove artifacts or otherwise adjust masks and hence alter the 3D image pair (or anaglyph) without iteratively sending fixes to any other workgroup.

FIG. 95 shows a workflow for iterative corrective workflow.

FIG. 96 shows an embodiment of the workflow enabled by one or more embodiments of the system in that each workgroup can perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove artifacts and otherwise correct work product from another workgroup without iterative delays associated with re-rendering/ray-tracing or sending work product back through the workflow for corrections.

FIG. 97 shows an embodiment of the rapid workflow for local modification of masks, gaps next to masks, depth maps, translation values such as UV or U Maps or any combination thereof to remove artifacts, create missing background information or otherwise adjust, alter, improve or otherwise modify previously ray traced or rendered images without re-rendering the entire image or stereoscopic images or otherwise re-ray tracing the image or stereoscopic images.

FIGS. 98A-D show Z Depth Alpha processing.

FIGS. 99A-D show UV Gap Detection processing.

FIGS. 100A-E show Gap Fill processing.

FIGS. 101A-E show Gap Blur Grain processing.

FIGS. 102A-B show Grain Merge processing.

FIG. 103 shows gap analysis processing that enables color coding of gaps based on their thickness to enable rapid identification and local modification of areas where artifacts may be visible or unacceptable for example wherein for example Red areas will likely need more attention than green areas and wherein the color also gives artists a quick view of areas of an image where internal portions of characters/objects are broken, e.g., where regions are not aligned with their neighbors correctly.

DETAILED DESCRIPTION OF THE INVENTION

Feature Film and TV series Data Preparation for Colorization/Depth enhancement: Feature films are tele-cined or transferred from 35 mm or 16 mm film using a high resolution scanner such as a 10-bit SPIRIT DATACINE® or similar device to HDTV (1920 by 1080 24P) or data-cined on a laser film scanner such as that manufactured by IMAGICA® Corp. of America at a larger format 2000 lines to 4000 lines and up to 16 bits of grayscale. The high resolution frame files are then converted to standard digital files such as uncompressed TIP files or uncompressed TGA files typically in 16 bit three-channel linear format or 8 bit three channel linear format. If the source data is HDTV, the 10-bit HDTV frame files are converted to similar TIF or TGA uncompressed files at either 16-bits or 8-bit per channel. Each frame pixel is then averaged such that the three channels are merged to create a single 16 bit channel or 8 bit channel respectively. Any other scanning technologies capable of scanning an existing film to digital format may be utilized. Currently, many movies are generated entirely in digital format, and thus may be utilized without scanning the movie. For digital movies that have associated metadata, for example for movies that make use of computer-generated characters, backgrounds or any other element, the metadata can be imported for example to obtain an alpha and/or mask and/or depth for the computer-generated element on a pixel-by-pixel or sub-pixel-by-sub-pixel basis. One format of a file that contains alpha/mask and depth data is the RGBAZ file format, of which one implementation is the EXR file format.

Digitization Telecine and Format Independence Monochrome elements of either 35 or 16 mm negative or positive film are digitized at various resolutions and bit depth within a high resolution film scanner such as that performed with a SPIRIT DATACINE® by PHILIPS® and EASTMAN KODAK® which transfers either 525 or 625 formats, HDTV, (HDTV) 1280×720/60 Hz progressive, 2K, DTV (ATSC) formats like 1920×1080/24 Hz/25 Hz progressive and 1920×1080/48 Hz/50 Hz segmented frame or 1920×1080 50I as examples. The invention provides improved methods for editing film into motion pictures. Visual images are transferred from developed motion picture film to a high definition video storage medium, which is a storage medium adapted to store images and to display images in conjunction with display equipment having a scan density substantially greater than that of an NTSC compatible video storage medium and associated display equipment. The visual images are also transferred, either from the motion picture film or the high definition video storage medium to a digital data storage format adapted for use with digital nonlinear motion picture editing equipment. After the visual images have been transferred to the high definition video storage medium, the digital nonlinear motion picture editing equipment is used to generate an edit decision list, to which the motion picture film is then conformed. The high definition video storage medium is generally adapted to store and display visual images having a scan density of at least 1080 horizontal lines. Electronic or optical transformation may be utilized to allow use of visual aspect ratios that make full use of the storage formats used in the method. This digitized film data as well as data already transferred from film to one of a multiplicity of formats such as HDTV are entered into a conversion system such as the HDTV STILL STORE 0 manufactured by AVICA® Technology Corporation. Such large scale digital buffers and data converters are capable of converting digital image to all standard formats such as 1080i HDTV formats such as 720 p, and 1080 p/24. An Asset Management System server provides powerful local and server back ups and archiving to standard SCSI devices, C2-level security, streamlined menu selection and multiple criteria database searches.

During the process of digitizing images from motion picture film the mechanical positioning of the film frame in the telecine machine suffers from an imprecision known as “film weave”, which cannot be fully eliminated. However various film registration and ironing or flattening gate assemblies are available such as that embodied in U.S. Pat. No. 5,328,073, Film Registration and Ironing Gate Assembly, which involves the use of a gate with a positioning location or aperture for focal positioning of an image frame of a strip film with edge perforations. Undersized first and second pins enter a pair of transversely aligned perforations of the film to register the image frame with the aperture. An undersized third pin enters a third perforation spaced along the film from the second pin and then pulls the film obliquely to a reference line extending between the first and second pins to nest against the first and second pins the perforations thereat and register the image frame precisely at the positioning location or aperture. A pair of flexible bands extending along the film edges adjacent the positioning location moves progressively into incrementally increasing contact with the film to iron it and clamp its perforations against the gate. The pins register the image frame precisely with the positioning location, and the bands maintain the image frame in precise focal position. Positioning can be further enhanced following the precision mechanical capture of images by methods such as that embodied in U.S. Pat. No. 4,903,131, Method For The Automatic Correction Of Errors In Image Registration During Film Scanning.

To remove or reduce the random structure known as grain within exposed feature film that is superimposed on the image as well as scratches or particles of dust or other debris which obscure the transmitted light various algorithms will be used such as that embodied in U.S. Pat. No. 6,067,125 Structure And Method For Film Grain Noise Reduction and U.S. Pat. No. 5,784,176,

Method of Image Noise Reduction Processing.

Reverse Editing of the Film Element Preliminary to Visual Database Creation:

The digital movie is broken down into scenes and cuts. The entire movie is then processed sequentially for the automatic detection of scene changes including dissolves, wipe-a-ways and cuts. These transitions are further broken down into camera pans, camera zooms and static scenes representing little or no movement. All database references to the above are entered into an edit decision list (EDT) within the database based on standard SMPTE time code or other suitable sequential naming convention. There exists, a great deal of technologies for detecting dramatic as well as subtle transitions in film content such as:

U.S. Pat. No. 5,959,697 Sep. 28, 1999 Method And System For Detecting Dissolve Transitions In A Video Signal

U.S. Pat. No. 5,920,360 Jul. 6, 1999 Method And System For Detecting Fade Transitions In A Video Signal

U.S. Pat. No. 5,841,512 Nov. 24, 1998 Methods Of Previewing And Editing Motion Pictures

U.S. Pat. No. 5,835,163 Nov. 10, 1998 Apparatus For Detecting A Cut In A Video

U.S. Pat. No. 5,767,923 Jun. 16, 1998 Method And System For Detecting Cuts In A Video Signal

U.S. Pat. No. 5,778,108 Jul. 6, 1996 Method And System For Detecting Transitional Markers Such As Uniform Fields In A Video Signal

U.S. Pat. No. 5,920,360 Jun. 7, 1999 Method And System For Detecting Fade Transitions In A Video Signal

All cuts that represent the same content such as in a dialog between two or more people where the camera appears to volley between the two talking heads are combined into one file entry for later batch processing.

An operator checks all database entries visually to ensure that:

1. Scenes are broken down into camera moves

2. Cuts are consolidated into single batch elements where appropriate

3. Motion is broken down into simple and complex depending on occlusion elements, number of moving objects and quality of the optics (e.g., softness of the elements, etc).

Pre-Production—scene analysis and scene breakdown for reference frame ID and data base creation:

Files are numbered using sequential SMPTE time code or other sequential naming convention. The image files are edited together at 24-frame/sec speed (without field related 3/2 pull down which is used in standard NTSC 30 frame/sec video) onto a DVD using ADOBE® AFTER EFFECTS® or similar programs to create a running video with audio of the feature film or TV series. This is used to assist with scene analysis and scene breakdown.

Scene and Cut Breakdown:

1. A database permits the entering of scene, cut, design, key frame and other critical data in time code format as well as descriptive information for each scene and cut.

2. Each scene cut is identified relative to camera technique. Time codes for pans, zooms, static backgrounds, static backgrounds with unsteady or drifting camera and unusual camera cuts that require special attention.

3. Designers and assistant designers study the feature film for color clues and color references or for the case of depth projects, the film is studied for depth clues, generally for non-standard sized objects. Research is provided for color/depth accuracy where applicable. The Internet for example may be utilized to determine the color of a particular item or the size of a particular item. For depth projects, knowing the size of an object allows for the calculation of the depth of an item in a scene for example. For depth projects related to converting two-dimensional movies to three-dimensional movies where depth metadata is available for computer-generated elements within the movies, the depth metadata can be scaled, or translated or otherwise normalized to the coordinate system or units used for the background and motion elements for example.

4. Single frames from each scene are selected to serve as design frames. These frames are color designed or metadata is imported for depth and/or mask and/or alpha for computer-generated elements, or depth assignments (see FIGS. 42-70) are made to background elements or motion elements in the frames to represent the overall look and feel of the feature film. Approximately 80 to 100 design frames are typical for a feature film.

5. In addition, single frames called key frames from each cut of the feature film are selected that contain all the elements within each cut that require color/depth consideration. There may be as many as 1,000 key frames. These frames will contain all the color/depth transform information necessary to apply color/depth to all sequential frames in each cut without additional color choices.

Color/Depth Selection:

Historical reference, studio archives and film analysis provides the designer with color references. Using an input device such as a mouse, the designer masks features in a selected single frame containing a plurality of pixels and assigns color to them using an HSL color space model based on creative considerations and the grayscale and luminance distribution underlying each mask. One or more base colors are selected for image data under each mask and applied to the particular luminance pattern attributes of the selected image feature. Each color selected is applied to an entire masked object or to the designated features within the luminance pattern of the object based on the unique gray-scale values of the feature under the mask.

A lookup table or color transform for the unique luminance pattern of the object or feature is thus created which represent the color to luminance values applied to the object. Since the color applied to the feature extends the entire range of potential grayscale values from dark to light the designer can insure that as the distribution of the gray-scale values representing the pattern change homogeneously into dark or light regions within subsequent frames of the movie such as with the introduction of shadows or bright light, the color for each feature also remains consistently homogeneous and correctly lighten or darken with the pattern upon which it is applied.

Depth can be imported for computer-generated objects where metadata exists and/or can be assigned to objects and adjusted using embodiments of the invention using an input device such as a mouse to assign objects particular depths including contour depths, e.g., geometric shapes such as an ellipsoid to a face for example. This allows objects to appear natural when converted to three-dimensional stereoscopic images. For computer-generated elements, the imported depth and/or alpha and/or mask shape can be adjusted if desired. Assigning a fixed distance to foreground objects tends to make the objects appear as cut-outs, i.e., flat. See also FIGS. 42-70.

Propagation of Mask Color Transform/Depth Information from One Frame to a Series of Subsequent Frames:

The masks representing designed selected color transforms/depth contours in the single design frame are then copied to all subsequent frames in the series of movie frames by one or more methods such as auto-fitting Bezier curves to edges, automatic mask fitting based on Fast Fourier Transforms and Gradient Descent Calculation tied to luminance patterns in a subsequent frame relative to the design frame or a successive preceding frames, mask paint to a plurality of successive frames by painting the object within only one frame, auto-fitting vector points to edges and copying and pasting individual masks or a plurality of masks to selected subsequent frames. In addition, depth information may be “tweened” to account for forward/backward motion or zooming with respect to the camera capture location. For computer-generated elements, the alpha and/or mask data is generally correct and may be skipped for reshaping processes since the metadata associated with computer-generated elements is obtained digitally from the original model of an object and hence does not require adjustment in general. (See FIG. 37C, step 3710 for setting mask fit location to border of CG element to potentially skip large amounts of processing in fitting masks in subsequent frames to reshape the edges to align a photographic element). Optionally, computer-generated elements may be morphed or reshaped to provide special effects not originally in a movie scene.

Single Frame Set Design and Colorization:

In embodiments of the invention, camera moves are consolidated and separated from motion elements in each scene by the creation of a montage or composite image of the background from a series of successive frames into a single frame containing all background elements for each scene and cut. The resulting single frame becomes a representation of the entire common background of a multiplicity of frames in a movie, creating a visual database of all elements and camera offset information within those frames.

In this manner most set backgrounds can be designed and colorized/depth enhanced in one pass using a single frame montage. Each montage is masked without regard to the foreground moving objects, which are masked separately. The background masks of the montage are then automatically extracted from the single background montage image and applied to the subsequent frames that were used to create the single montage using all the offsets stored in the image data for correctly aligning the masks to each subsequent frame.

There is a basic formula in filmmaking that varies little within and between feature films (except for those films employing extensive hand-held or stabilized camera shots.) Scenes are composed of cuts, which are blocked for standard camera moves, i.e., pans, zooms and static or locked camera angles as well as combinations of these moves. Cuts are either single occurrences or a combination of cut-a-ways where there is a return to a particular camera shot such as in a dialog between two individuals. Such cut-a-ways can be considered a single scene sequence or single cut and can be consolidate in one image-processing pass.

Pans can be consolidated within a single frame visual database using special panorama stitching techniques but without lens compensation. Each frame in a pan involves:

1. The loss of some information on one side, top and/or bottom of the frame

2. Common information in the majority of the frame relative to the immediately preceding and subsequent frames and

3. New information on the other side, top and/or bottom of the frame.

By stitching these frames together based on common elements within successive frames and thereby creating a panorama of the background elements a visual database is created with all pixel offsets available for referencing in the application of a single mask overlay to the complete set of sequential frames.

Creation of a Visual Database:

Since each pixel within a single frame visual database of a background corresponds to an appropriate address within the respective “raw” (unconsolidated) frame from which it was created, any designer determined masking operation and corresponding masking lookup table designation applied to the visual database will be correctly applied to each pixel's appropriate address within the raw film frames that were used to create the single frame composite.

In this manner, sets for each scene and cut are each represented by a single frame (the visual database) in which pixels have either single or multiple representations within the series of raw frames from which they were derived. All masking within a single visual database frame will create a one-bit mask per region representation of an appropriate lookup table that corresponds to either common or unique pixel addresses within the sequential frames that created the single composite frame. These address-defined masking pixels are applied to the full resolution frames where total masking is automatically checked and adjusted where necessary using feature, edge detection and pattern recognition routines. Where adjustments are required, i.e., where applied masked region edges do not correspond to the majority of feature edges within the gray scale image, a “red flag” exception comment signals the operator that frame-by-frame adjustments may be necessary.

Single Frame Representation of Motion within Multiple Frames:

The differencing algorithm used for detecting motion objects will generally be able to differentiate dramatic pixel region changes that represent moving objects from frame to frame. In cases where cast shadows on a background from a moving object may be confused with the moving object the resulting masks will be assigned to a default alpha layer that renders that part of the moving object mask transparent. In some cases an operator using one or more vector or paint tools will designate the demarcation between the moving object and cast shadow. In most cases however, the cast shadows will be detected as an extraneous feature relative to the two key motion objects. In this invention cast shadows are handled by the background lookup table that automatically adjusts color along a luminance scale determined by the spectrum of light and dark gray scale values in the image.

Action within each frame is isolated via differencing or frame-to-frame subtraction techniques that include vector (both directional and speed) differencing (i.e., where action occurs within a pan) as well as machine vision techniques, which model objects and their behaviors. Difference pixels are then composited as a single frame (or isolated in a tiling mode) representing a multiplicity of frames thus permitting the operator to window regions of interest and otherwise direct image processing operations for computer controlled subsequent frame masking.

As with the set or background montage discussed above, action taking place in multiple frames within a scene can be represented by a single frame visual database in which each unique pixel location undergoes appropriate one bit masking from which corresponding lookup tables are applied. However, unlike the set or background montage in which all color/depth is applied and designated within the single frame pass, the purpose of creating an action composite visual data base is to window or otherwise designate each feature or region of interest that will receive a particular mask and apply region of interest vectors from one key frame element to subsequent key frame elements thus provide operator assistance to the computer processing that will track each region of interest.

During the design phase, masks are applied to designer designated regions of interest for a single instance of a motion object appearing within the background (i.e., a single frame of action appears within the background or stitched composited background in the proper x, y coordinates within the background corresponding to the single frame of action from which it was derived). Using an input device such as a mouse the operator uses the following tools in creating the regions of interest for masking. Alternatively, projects having associated computer-generated element metadata may import and if necessary, scale the metadata to the units utilized for depth in the project. Since these masks are digitally created, they can be assumed to be accurate throughout the scene and thus the outlines and depths of the computer-generated areas may be ignored for reshaping operations. Elements that border these objects, may thus be more accurately reshaped since the outlines of the computer-generated elements are taken as correct. Hence, even for computer-generated elements having the same underlying gray scale of a contiguous motion or background element, the shape of the mask at the junction can be taken to be accurate even though there is no visual difference at the junction. Again, see FIG. 37C, step 3710 for setting mask fit location to border of CG element to potentially skip large amounts of processing in fitting masks in subsequent frames to reshape the edges to align a photographic element

1. A combination of edge detection algorithms such as standard Laplacian filters and pattern recognition routines

2. Automatic or assisted closing of a regions

3. Automatic seed fill of selected regions

4. Bimodal luminance detection for light or dark regions

5. An operator-assisted sliding scale and other tools create a “best fit” distribution index corresponding to the dynamic range of the underlying pixels as well as the underlying luminance values, pattern and weighted variables

6. Subsequent analysis of underlying gray scale, luminance, area, pattern and multiple weighting characteristics relative to immediately surrounding areas creating a unique determination/discrimination set called a Detector File.

In the pre-production key frame phase—The composited single, design motion database described above is presented along with all subsequent motion inclusive of selected key frame motion objects. All motion composites can be toggled on and off within the background or viewed in motion within the background by turning each successive motion composite on and off sequentially.

Key Frame Motion Object Creation: The operator windows all masked regions of interest on the design frame in succession and directs the computer by various pointing instruments and routines to the corresponding location (regions of interest) on selected key frame motion objects within the visual database thereby reducing the area on which the computer must operate (i.e., the operator creates a vector from the design frame moving object to each subsequent key frame moving object following a close approximation to the center of the region of interest represented within the visual database of the key frame moving object. This operator-assisted method restricts the required detection operations that must be performed by the computer in applying masks to the corresponding regions of interest in the raw frames).

In the production phase—The composited key frame motion object database described above is presented along with all subsequent motion inclusive of fully masked selected key frame motion objects. As above, all motion composites can be toggled on and off within the background or sequentially turned on and off in succession within the background to simulate actual motion. In addition, all masked regions (regions of interest) can be presented in the absence of their corresponding motion objects. In such cases the one-bit color masks are displayed as either translucent or opaque arbitrary colors.

During the production process and under operator visual control, each region of interest within subsequent motion object frames, between two key motion object frames undergoes a computer masking operation. The masking operation involves a comparison of the masks in a preceding motion object frame with the new or subsequent Detector File operation and underlying parameters (i.e., mask dimensions, gray scale values and multiple weighting factors that lie within the vector of parameters in the subsequent key frame motion object) in the successive frame. This process is aided by the windowing or pointing (using various pointing instruments) and vector application within the visual database. If the values within an operator assisted detected region of the subsequent motion object falls within the range of the corresponding region of the preceding motion object, relative to the surrounding values and if those values fall along a trajectory of values (vectors) anticipated by a comparison of the first key frame and the second key frame then the computer will determine a match and will attempt a best fit.

The uncompressed, high resolution images all reside at the server level, all subsequent masking operations on the regions of interest are displayed on the compressed composited frame in display memory or on a tiled, compressed frame in display memory so that the operator can determine correct tracking and matching of regions. A zoomed region of interest window showing the uncompressed region is displayed on the screen to determine visually the region of interest best fit. This high-resolution window is also capable of full motion viewing so that the operator can determine whether the masking operation is accurate in motion.

In a first embodiment as shown in FIG. 1, a plurality of feature film or television film frames 14 a-n representing a scene or cut in which there is a single instance or perceptive of a background 16 (FIG. 3). In the scene 10 shown, several actors or motion elements 18′, 18″ and 18″′ are moving within an outdoor stage and the camera is performing a pan left. FIG. 1 shows selected samples of the 120 total frames 14 making up the 5-second pan.

In FIG. 2, an isolated background 16 processed scene from the plurality of frames 14 a-n represented in FIG. 1 in which all motion elements 18 are removed using various subtraction and differencing techniques. The separate frames that created the pan are combined into a visual database in which unique and common pixels from each of the 120 frames 14 composing the original pan are represented in the single composite background image 12 shown in FIG. 3. The single background image 12 is then used to create a background mask overlay 20 representing designer selected color lookup tables in which dynamic pixel colors automatically compensate or adjust for moving shadows and other changes in luminance. For depth projects, any object in the background may be assigned any depth. A variety of tools may be utilized to perform the assignment of depth information to any portion of the background including paint tools, geometric icon based tools that allow setting a contour depth to an object, or text field inputs to allow for numeric inputs. The composite background shown in FIG. 2 for example may also have a ramp function assigned to allow for a nearer depth to be assigned to the left portion of the scene and a linear increase in depth to the right of the image to be automatically assigned. See also FIGS. 42-70.

In one illustrative embodiment of this invention, operator assisted and automated operations are used to detect obvious anchor points represented by clear edge detected intersects and other contiguous edges n each frame 14 making up the single composite image 12 and over laid mask 20. These anchor points are also represented within the composite image 12 and are used to aide in the correct assignment of the mark to each frame 14 represented by the single composite image 12.

Anchor points and objects and/or areas that are clearly defined by closed or nearly closed edges are designed as a single mask area and given a single lookup table. Within those clearly delineated regions polygons are created of which anchor points are dominant points. Where there is no clear edge detected to create a perfectly closed region, polygons are generated using the edge of the applied mask.

The resulting polygon mesh includes the interior of anchor point dominant regions plus all exterior areas between those regions.

Pattern parameters created by the distribution of luminance within each polygon are registered in a database for reference when corresponding polygonal addresses of the overlying masks are applied to the appropriate addresses of the frames that were used to create the composite single image 12.

In FIG. 3, a representative sample of each motion object (M-Object) 18 in the scene 10 receives a mask overlay that represents designer selected color lookup tables/depth assignments in which dynamic pixel colors automatically compensate or adjust for moving shadows and other changes in luminance as the M-Object 18 moves within the scene 10. The representative sample are each considered Key M-Objects 18 that are used to define the underlying patterns, edges, grouped luminance characteristics, etc., within the masked M-Object 18. These characteristics are used to translate the design masks from one Key M-Object 18 a to subsequent M-Objects 18 b along a defined vector of parameters leading to Key M-Object 18 c, each Subsequent M-Object becoming the new Key M-Object in succession as masks are applied. As shown, Key M-Object 18 a may be assigned a depth of 32 feet from the camera capture point while Key M-Object 18 c may be assigned a depth of 28 feet from the camera capture point. The various depths of the object may be “tweened” between the various depth points to allow for realistic three-dimensional motion to occur within the cut without for example requiring wire frame models of all of the objects in the objects in a frame.

As with the background operations above, operator assisted and automated operations are used to detect obvious anchor points represented by clear edge detected intersects and other contiguous edges in each motion object used to create a keyframe.

Anchor points and specific regions of interest within each motion object that are clearly defined by closed or nearly closed edges are designated as a single mask area and given a single lookup table. Within those clearly delineated regions, polygons are created of which anchor points are dominant points. Where there is no clear edge detected to create a perfectly closed region, polygons are generated using the edge of the applied mask.

The resulting polygon mesh includes the interior of the anchor point dominant regions plus all exterior areas between those regions.

Pattern parameters created by the distribution of luminance values within each polygon are registered in a database for reference when corresponding polygonal addresses of the overlying masks are applied to the appropriate addresses of the frames that were used to create the composite single frame 12.

The greater the polygon sampling the more detailed the assessment of the underlying luminance values and the more precise the fit of the overlying mask.

Subsequent or in-between motion key frame objects 18 are processed sequentially. The group of masks comprising the motion key frame object remains in its correct address location in the subsequent frame 14 or in the subsequent instance of the next motion object 18. The mask is shown as an opaque or transparent color. An operator indicates each mask in succession with a mouse or other pointing device and along with its corresponding location in the subsequent frame and/or instance of the motion object. The computer then uses the prior anchor point and corresponding polygons representing both underlying luminance texture and mask edges to create a best fit to the subsequent instance of the motion object.

The next instance of the motion object 18 is operated upon in the same manner until all motion objects 18 in a cut 10 and/or scene are completed between key motion objects.

In FIG. 4, all mask elements of the scene 10 are then rendered to create a fully colored and/or depth enhanced frame in which M-Object 18 masks are applied to each appropriate frame in the scene followed by the background mask 20, which is applied only where there is no pre-existing mask in a Boolean manner. Foreground elements are then applied to each frame 14 according to a pre-programmed priority set. Aiding the accurate application of background masks 20 are vector points which are applied by the designer to the visual database at the time of masking where there are well defined points of reference such as edges and/or distinct luminance points. These vectors create a matrix of reference points assuring accuracy of rendering masks to the separate frames that compose each scene. The applied depths of the various objects determine the amount of horizontal translation applied when generating left and right viewpoints as utilized in three-dimensional viewing as one skilled in the art will appreciate. In one or more embodiments of the invention, the desired objects may be dynamically displayed while shifting by an operator set and observe a realistic depth. In other embodiments of the invention, the depth value of an object determines the horizontal shift applied as one skilled in the art will recognize and which is taught in at least U.S. Pat. No. 6,031,564, to Ma et al., the specification of which is hereby incorporated herein by reference.

The operator employs several tools to apply masks to successive movie frames.

Display: A key frame that includes all motion objects for that frame is fully masked and loaded into the display buffer along with a plurality of subsequent frames in thumbnail format; typically 2 seconds or 48 frames.

FIGS. 5A and 5B show a series of sequential frames 14 a-n loaded into display memory in which one frame 14 is fully masked with the background (key frame) and ready for mask propagation to the subsequent frames 14 via automatic mask fitting methods.

All frames 14 along with associated masks and/or applied color transforms/depth enhancements can also be displayed sequentially in real-time (24 frames/sec) using a second (child) window to determine if the automatic masking operations are working correctly. In the case of depth projects, stereoscopic glasses or red/blue anaglyph glasses may be utilized to view both viewpoints corresponding to each eye. Any type of depth viewing technology may be utilized to view depth enhanced images including video displays that require no stereoscopic glasses yet which utilizes more than two image pairs which may be created utilizing embodiments of the invention.

FIGS. 6A and 6B show the child window displaying an enlarged and scalable single image of the series of sequential images in display memory. The Child window enables the operator to manipulate masks interactively on a single frame or in multiple frames during real time or slowed motion.

Mask Modification: Masks can be copied to all or selected frames and automatically modified in thumbnail view or in the preview window. In the preview window mask modification takes place on either individual frames in the display or on multiple frames during real-time motion.

Propagation of Masks to Multiple Sequential Frames in Display Memory: Key Frame masks of foreground motion objects are applied to all frames in the display buffer using various copy functions:

Copy all masks in one frame to all frames;

Copy all masks in one frame to selected frames;

Copy selected mask or masks in one frame to all frames;

Copy selected mask or masks in one frame to selected frames; and

Create masks generated in one frame with immediate copy at the same addresses in all other frames.

Refining now to FIGS. 7A and 7B, a single mask (flesh) is propagated automatically to all frames 14 in the display memory. The operator could designate selective frames to apply the selected mask or indicate that it is applied to all frames 14. The mask is a duplication of the initial mask in the first fully masked frame. Modifications of that mask occur only after they have been propagated.

As shown in FIG. 8, all masks associated with the motion object are propagated to all sequential frames in display memory. The images show the displacement of the underlying image data relative to the mask information.

None of the propagation methods listed above actively fit the masks to objects in the frames 14. They only apply the same mask shape and associated color transform information from one frame, typically the key frame to all other frames or selected frames.

Masks are adjusted to compensate for object motion in subsequent frames using various tools based on luminance, pattern and edge characteristics of the image.

Automatic Mask Fitting: Successive frames of a feature film or TV episode exhibit movement of actors and other objects. These objects are designed in a single representative frame within the current embodiment such that operator selected features or regions have unique color transformations identified by unique masks, which encompass the entire feature. The purpose of the mask-fitting tool is to provide an automated means for correct placement and reshaping of a each mask region of interest (ROI) in successive frames such that the mask accurately conforms to the correct spatial location and two dimensional geometry of the ROI as it displaces from the original position in the single representative frame. This method is intended to permit propagation of a mask region from an original reference or design frame to successive frames, and automatically enabling it to adjust shape and location to each image displacement of the associated underlying image feature. For computer-generated elements, the associated masks are digitally created and can be assumed to be accurate throughout the scene and thus the outlines and depths of the computer-generated areas may be ignored for automatic mask fitting or reshaping operations. Elements that border these objects, may thus be more accurately reshaped since the outlines of the computer-generated elements are taken as correct. Hence, even for computer-generated elements having the same underlying gray scale of a contiguous motion or background element, the shape of the mask at the junction can be taken to be accurate even though there is no visual difference at the junction. Hence, whenever automatic mask fitting of mask takes shape with a border of a computer-generated element mask, the computer-generated element mask can be utilized to define the border of the operator-defined mask as per step 3710 of FIG. 37C. This saves processing time since automatic mask fitting in a scene with numerous computer-generated element masks can be minimized.

The method for automatically modifying both the location and correctly fitting all masks in an image to compensate for movement of the corresponding image data between frames involves the following:

Set Reference Frame Mask and Corresponding Image Data:

1. A reference frame (frame 1) is masked by an operator using a variety of means such as paint and polygon tools so that all regions of interest (i.e., features) are tightly covered.

2. The minimum and maximum x,y coordinate values of each masked region are calculated to create rectangular bounding boxes around each masked region encompassing all underlying image pixels of each masked region.

3. A subset of pixels are identified for each region of interest within its bounding rectangle (i.e., every 10th pixel)

Copy Reference Frame Mask and Corresponding Image Data To All Subsequent Frames: The masks, bounding boxes and corresponding subset of pixel locations from the reference frame are copied over to all subsequent frames by the operator.

Approximate Offset of Regions Between Reference Frame and the Next Subsequent Frame:

1. Fast Fourier Transform (FFT) are calculated to approximate image data displacements between frame 1 and frame 2

2. Each mask in frame 2 with the accompanying bounding boxes are moved to compensate for the displacement of corresponding image data from frame 1 using the FFT calculation.

3. The bounding box is augmented by an additional margin around the region to accommodate other motion and shape morphing effects.

Fit Masks to the New Location:

1. Using the vector of offset determined by the FFT, a gradient decent of minimum errors is calculated in the image data underlying each mask by:

2. Creating a fit box around each pixel within the subset of the bounding box

3. Calculating a weighed index of all pixels within the fit box using a bilinear interpolation method.

4. Determining offset and best fit to each subsequent frame use Gradient Decent calculations to fit the mask to the desired region.

Mask fit initialization: An operator selects image features in a single selected frame of a scene (the reference frame) and creates masks with contain all color transforms (color lookup tables) for the underlying image data for each feature. The selected image features that are identified by the operator have well-defined geometric extents which are identified by scanning the features underlying each mask for minimum and maximum x, y coordinate values, thereby defining a rectangular bounding box around each mask.

The Fit Grid used for Fit Grid Interpolation: For optimization purposes, only a sparse subset of the relevant mask-extent region pixels within each bounding box are fit with the method; this subset of pixels defines a regular grid in the image, as labeled by the light pixels of FIG. 9A.

The “small dark” pixels shown in FIG. 9B are used to calculate a weighed index using bilinear interpolation. The grid spacing is currently set at 10 pixels, so that essentially no more than 1 in 50 pixels are presently fit with a gradient descent search. This grid spacing could be a user controllable parameter.

Fast Fourier Transform (FFT) to Estimate Displacement Values: Masks with corresponding rectangular bounding boxes and fit grids are copied to subsequent frames. Forward and inverse FFTs are calculated between the reference frame the next subsequent frame to determine the x,y displacement values of image features corresponding to each mask and bounding box. This method generates a correlation surface, the largest value of which provides a “best fit” position for the corresponding feature's location in the search image. Each mask and bounding box is then adjusted within the second frame to the proper x,y locations.

Fit Value Calculation (Gradient Descent Search): The FFT provides a displacement vector, which directs the search for ideal mask fitting using the Gradient Descent Search method. Gradient descent search requires that the translation or offset be less than the radius of the basin surrounding the minimum of the matching error surface. A successful FFT correlation for each mask region and bounding box will create the minimum requirements.

Searching for a Best Fit on the Error Surface: An error surface calculation in the Gradient Descent Search method involves calculating mean squared differences of pixels in the square fit box centered on reference image pixel (x0, y0), between the reference image frame and the corresponding (offset) location (x, y) on the search image frame, as shown in FIGS. 10A, B, C and D.

Corresponding pixel values in two (reference and search) fit boxes are subtracted, squared, summed/accumulated, and the square-root of the resultant sum finally divided by the number of pixels in the box (#pixels=height×width=height2) to generate the root mean square fit difference (“Error”) value at the selected fit search location Error(x0,y0;x,y)={Σi□Σ□(reference box(x0,y0)pixel[i,j]−search box(x,y)pixel[i,j])2}/(height2)

Fit Value Gradient: The displacement vector data derived from the FFT creates a search fit location, and the error surface calculation begins at that offset position, proceeding down (against) the gradient of the error surface to a local minimum of the surface, which is assumed to be the best fit. This method finds best fit for each next frame pixel or groups of pixels based on the previous frame, using normalized squared differences, for instance in a 10×10 box and finding a minimum down the mean squared difference gradients. This technique is similar to a cross correlation but with a restricted sampling box for the calculation. In this way the corresponding fit pixel in the previous frame can be checked for its mask index, and the resulting assignment is complete.

FIGS. 11A, B and C show a second search box derived from a descent down the error surface gradient (evaluated separately), for which the evaluated error function is reduced, possibly minimized, with respect to the original reference box (evident from visual comparison of the boxes with the reference box in FIGS. 10A, B, C and D).

The error surface gradient is calculated as per definition of the gradient. Vertical and horizontal error deviations are evaluated at four positions near the search box center position, and combined to provide an estimate of the error gradient for that position. The gradient component evaluation is explained with the help of FIG. 12.

The gradient of a surface S at coordinate (x, y) is given by the directional derivatives of the surface: gradient(x,y)=[dS(x,y)/dx,dS(x,y)/dy],

which for the discrete case of the digital image is provided by: gradient(x,y)=[(Error(x+dx,y)−Error(x−dx,y))/(2*dx),(Error(x,y+dy)−Error(x,y−dy))/(2*dy)]

where dx, dy are one-half the box-width or box-height, also defined as the fit-box “box-radius”: box-width=box-height=2×box-radius+1

Note that with increasing box-radius, the fit-box dimensions increase and consequently the size and detail of an image feature contained therein increase as well; the calculated fit accuracy is therefore improved with a larger box and more data to work with, but the computation time per fit (error) calculation increases as the square of the radius increase. For any computer-generated element mask area pixel that is found at a particular pixel x, y location, then that location is taken to be the edge of the overlying operated-defined mask and mask fitting continues at other pixel locations until all pixels of the mask are checked

Previous vs. Propagated Reference Images: The reference image utilized for mask fitting is usually an adjacent frame in a film image-frame sequence. However, it is sometimes preferable to use an exquisitely fit mask as a reference image (e.g. a key frame mask, or the source frame from which mask regions were propagated/copied). The present embodiment provides a switch to disable “adjacent” reference frames, using the propagated masks of the reference image if that frame is defined by a recent propagation event.

The process of mask fitting: In the present embodiment the operator loads n frames into the display buffer. One frame includes the masks that are to be propagated and fitted to all other frames. All or some of the mask(s) are then propagated to all frames in the display buffer. Since the mask-fitting algorithm references the preceding frame or the first frame in the series for fitting masks to the subsequent frame, the first frame masks and/or preceding masks must be tightly applied to the objects and/or regions of interest. If this is not done, mask errors will accumulate and mask fitting will break down. The operator displays the subsequent frame, adjusts the sampling radius of the fit and executes a command to calculate mask fitting for the entire frame. The execution command can be a keystroke or mouse-hotkey command.

As shown in FIG. 13, a propagated mask in the first sequential instance where there is little discrepancy between the underlying image data and the mask data. The dress mask and hand mask can be clearly seen to be off relative to the image data.

FIG. 14 shows that by using the automatic mask fitting routine, the mask data adjusts to the image data by referencing the underlying image data in the preceding image.

In FIG. 15, the mask data in later images within the sequence show marked discrepancy relative to the underlying image data. Eye makeup, lipstick, blush, hair, face, dress and hand image data are all displaced relative to the mask data.

As shown in FIG. 16, the mask data is adjusted automatically based on the underlying image data from the previous mask and underlying image data. In this FIG. 13, the mask data is shown with random colors to show the regions that were adjusted automatically based on underlying pattern and luminance data. The blush and eye makeup did not have edge data to reference and were auto-adjusted on the basis of luminance and grayscale pattern.

In FIG. 17, mask data from FIG. 16 is shown with appropriate color transforms after whole frame automatic mask fitting. The mask data is adjusted to fit the underlying luminance pattern based on data from the previous frame or from the initial key frame.

Mask Propagation With Bezier and Polygon Animation Using Edge Snap: Masks for motion objects can be animated using either Bezier curves or polygons that enclose a region of interest. A plurality of frames are loaded into display memory and either Bezier points and curves or polygon points are applied close to the region of interest where the points automatically snap to edges detected within the image data. Once the object in frame one has been enclosed by the polygon or Bezier curves the operator adjusts the polygon or Bezier in the last frame of the frames loaded in display memory. The operator then executes a fitting routine, which snaps the polygons or Bezier points plus control curves to all intermediate frames, animating the mask over all frames in display memory. The polygon and Bezier algorithms include control points for rotation, scaling and move-all to handle camera zooms, pans and complex camera moves.

In FIG. 18, polygons are used to outline a region of interest for masking in frame one. The square polygon points snap to the edges of the object of interest. Using a Bezier curve the Bezier points snap to the object of interest and the control points/curves shape to the edges.

As disclosed in FIG. 19, the entire polygon or Bezier curve is carried to a selected last frame in the display memory where the operator adjusts the polygon points or Bezier points and curves using the snap function, which automatically snaps the points and curves to the edges of the object of interest.

As shown in FIG. 20, if there is a marked discrepancy between the points and curves in frames between the two frames where there was an operator interactive adjustment, the operator will further adjust a frame in the middle of the plurality of frames where there is maximum error of fit.

As shown in FIG. 21, when it is determined that the polygons or Bezier curves are correctly animating between the two adjusted frames, the appropriate masks are applied to all frames. In these figures, the arbitrary mask color is seen filling the polygon or Bezier curves.

FIG. 22 shows the resulting masks from a polygon or Bezier animation with automatic point and curve snap to edges. The brown masks are the color transforms and the green masks are the arbitrary color masks. For depth projects, areas that have been depth assigned may be of one color while those areas that have yet to be depth assigned may be of another color for example.

Colorization/Depth Enhancement of Backgrounds in feature films and television episode: The process of applying mask information to sequential frames in a feature film or television episode is known, but is laborious for a number of reasons. In all cases, these processes involve the correction of mask information from frame to frame to compensate for the movement of underlying image data. The correction of mask information not only includes the re-masking of actors and other moving objects within a scene or cut but also correction of the background and foreground information that the moving objects occlude or expose during their movement. This has been particularly difficult in camera pans where the camera follows the action to the left, right, up or down in the scene cut. In such cases the operator must not only correct for movement of the motion object, the operator must also correct for occlusion and exposure of the background information plus correct for the exposure of new background information as the camera moves to new parts of the background and foreground. Typically these instances greatly increase the time and difficulty factor of colorizing a scene cut due to the extreme amount of manual labor involved. Embodiments of the invention include a method and process for automatically colorizing/depth enhancing a plurality of frames in scenes cuts that include complex camera movements as well as scene cuts where there is camera weave or drifting cameras movement that follows erratic action of the motion objects.

Camera Pans: For a pan camera sequence, the background associated with non-moving objects in a scene form a large part of the sequence. In order to colorize/depth enhance a large amount of background objects for a pan sequence, a mosaic that includes the background objects for an entire pan sequence with moving objects removed is created. This task is accomplished with a pan background stitcher tool. Once a background mosaic of the pan sequence is generated, it can be colorized/depth enhanced once and applied to the individual frames automatically, without having to manually colorize/depth assign the background objects in each frame of the sequence.

The pan background stitcher tool generates a background image of a pan sequence using two general operations. First, the movement of the camera is estimated by calculating the transformation needed to align each frame in the sequence with the previous frame. Since moving objects form a large portion of cinematic sequences, techniques are used that minimize the effects of moving objects on the frame registration. Second, the frames are blended into a final background mosaic by interactively selecting two pass blending regions that effectively remove moving objects from the final mosaic.

Background composite output data includes a greyscale/(or possibly color for depth projects) image file of standard digital format such as TIFF image file (bkg.*.tif) comprised of a background image of the entire pan shot, with the desired moving objects removed, ready for color design/depth assignments using the masking operations already described, and an associated background text data file needed for background mask extraction after associated background mask/colorization/depth data components (bkg.*.msk, bkg.*lut, . . . ) have been established. The background text data file provides filename, frame position within the mosaic, and other frame-dimensioning information for each constituent (input) frame associated with the background, with the following per line (per frame) content: Frame-filename, frame-x-position, frame-y-position, frame-width, frame-height, frame-left-margin-x-max, frame-right-margin-x-min. Each of the data fields are integers except for the first (frame-filename), which is a string.

Generating Transforms: In order to generate a background image for a pan camera sequence, the motion of the camera first is calculated. The motion of the camera is determined by examining the transformation needed to bring one frame into alignment with the previous frame. By calculating the movement for each pair of consecutive frames in the sequence, a map of transformations giving each frame's relative position in the sequence can be generated.

Translation Between Image Pairs: Most image registration techniques use some form of intensity correlation. Unfortunately, methods based on pixel intensities will be biased by any moving objects in the scene, making it difficult to estimate the movement due to camera motion. Feature based methods have also been used for image registration. These methods are limited by the fact that most features occur on the boundaries of moving objects, also giving inaccurate results for pure camera movement. Manually selecting feature points for a large number of frames is also too costly.

The registration method used in the pan stitcher uses properties of the Fourier transform in order to avoid bias towards moving objects in the scene. Automatic registration of frame pairs is calculated and used for the final background image assembly.

Fourier Transform of an Image Pair: The first step in the image registration process consists of taking the Fourier transform of each image. The camera motion can be estimated as a translation. The second image is translated by a certain amount given by: I ₂(x,y)=I ₁(x−x ₀ ,y−y ₀).  (1)

Taking the Fourier transform of each image in the pair yields the following relationship: F ₂(α,β)=e ^(−j·2π·(αx) ⁰ ^(−βy) ⁰ ⁾ ·F ₁(α,β).  (2)

Phase Shift Calculation: The next step involves calculating the phase shift between the images. Doing this results in an expression for the phase shift in terms of the Fourier transform of the first and second image:

$\begin{matrix} {{\mathbb{e}}^{{{- j} \cdot 2}\;{\pi \cdot {({{\alpha\; x_{0}} - {\beta\; y_{0}}})}}} = {\frac{F_{1}^{*} \cdot F_{2}}{{F_{1}^{*} \cdot F_{2}}}.}} & (3) \end{matrix}$

Inverse Fourier Transform

By taking the inverse Fourier transform of the phase shift calculation given in (3) results in delta function whose peak is located at the translation of the second image.

$\begin{matrix} {{\delta\left( {{x - x_{0}},{y - y_{0}}} \right)} = {{F^{- 1}\left\lbrack {\mathbb{e}}^{{{- j} \cdot 2}\;{\pi \cdot {({{\alpha\; x_{0}} - {\beta\; y_{0}}})}}} \right\rbrack} = {F^{- 1}\left\lbrack \frac{F_{1}^{*} \cdot F_{2}}{{F_{1}^{*} \cdot F_{2}}} \right\rbrack}}} & (4) \end{matrix}$

Peak Location: The two-dimensional surface that results from (4) will have a maximum peak at the translation point from the first image to the second image. By searching for the largest value in the surface, it is simple to find the transform that represents the camera movement in the scene. Although there will be spikes present due to moving objects, the dominant motion of the camera should represent the largest peak value. This calculation is performed for every consecutive pair of frames in the entire pan sequence.

Dealing with Image Noise: Unfortunately, spurious results can occur due to image noise which can drastically change the results of the transform calculation. The pan background stitcher deals with these outliers using two methods that detect and correct erroneous cases: closest peak matching and interpolated positions. If these corrections fail for a particular image pair, the stitching application has an option to manually correct the position of any pair of frames in the sequence.

Closest Matching Peak: After the transform is calculated for an image pair, the percent difference between this transform and the previous transform is determined. If the difference is higher than a predetermined threshold than a search for neighboring peaks is done. If a peak is found that is a closer match and below the difference threshold, then this value is used instead of the highest peak value.

This assumes that for a pan camera shot, the motion with be relatively steady, and the differences between motions for each frame pair will be small. This corrects for the case where image noise may cause a peak that is slightly higher that the true peak corresponding to the camera transformation.

Interpolating Positions: If the closest matching peak calculation fails to yield a reasonable result given by the percent difference threshold, then the position is estimated based on the result from the previous image pair. Again, this gives generally good results for a steady pan sequence since the difference between consecutive camera movements should be roughly the same. The peak correlation values and interpolated results are shown in the stitching application, so manual correction can be done if needed.

Generating the Background: Once the relative camera movement for each consecutive frame pair has been calculated, the frames can be composited into a mosaic which represents the entire background for the sequence. Since the moving objects in the scene need to be removed, different image blending options are used to effectively remove the dominant moving objects in the sequence.

Assembling the Background Mosaic: First a background image buffer is generated which is large enough to span the entire sequence. The background can be blended together in a single pass, or if moving objects need to be removed, a two-pass blend is used, which is detailed below. The position and width of the blend can be edited in the stitching application and can be set globally set or individually set for each frame pair. Each blend is accumulated into the final mosaic and then written out as a single image file.

Two Pass Blending: The objective in two-pass blending is to eliminate moving objects from the final blended mosaic. This can be done by first blending the frames so the moving object is completely removed from the left side of the background mosaic. An example is shown in FIG. 23, where the character can is removed from the scene, but can still be seen in the right side of the background mosaic. FIG. 23. In the first pass blend shown in FIG. 23, the moving character is shown on the stairs to the right

A second background mosaic is then generated, where the blend position and width is used so that the moving object is removed from the right side of the final background mosaic. An example of this is shown in FIG. 24, where the character can is removed from the scene, but can still be seen the left side of the background mosaic. In the second pass blend as shown in FIG. 24, the moving character is shown on the left.

Finally, the two-passes are blended together to generate the final blended background mosaic with the moving object removed from the scene. The final background corresponding to FIGS. 23 and 24 is shown in FIG. 25. As shown in FIG. 25, the final blended background with moving character is removed.

In order to facilitate effective removal of moving objects, which can occupy different areas of the frame during a pan sequence, the stitcher application has on option to interactively set the blending width and position for each pass and each frame individually or globally. An example screen shot from the blend editing tool, showing the first and second pass blend positions and widths, can be seen in FIG. 26, which is a screen shot of the blend-editing tool.

Background Text Data Save: An output text data file containing parameter values relevant for background mask extraction as generated from the initialization phase described above. As mentioned above, each text data record includes: Frame-filename frame-x-position frame-y-position frame-width frame-height frame-left-margin-x-max frame-right-margin-x-min.

The output text data filename is composed from the first composite input frame rootname by prepending the “bkg.” prefix and appending the “.txt” extension.

EXAMPLE

Representative lines output text data file called “bkga.00233.txt” that may include data from 300 or more frames making up the blended image

4.00233.tif 0 0 1436 1080 0 1435

4.00234.tif 7 0 1436 1080 0 1435

4.00235.tif 20 0 1436 1080 0 1435

4.00236.tif 37 0 1436 1080 0 1435

4.00237.tif 58 0 1436 1080 0 1435

Image offset information used to create the composite representation of the series of frames is contained within a text file associated with the composite image and used to apply the single composite mask to all the frames used to create the composite image.

In FIG. 27, sequential frames representing a camera pan are loaded into memory. The motion object (butler moving left to the door) has been masked with a series of color transform information leaving the background black and white with no masks or color transform information applied. Alternatively for depth projects, the motion object may be assigned a depth and/or depth shape. See FIGS. 42-70.

In FIG. 28, six representative sequential frames of the pan above are displayed for clarity.

FIG. 29 show the composite or montage image of the entire camera pan that was built using phase correlation techniques. The motion object (butler) included as a transparency for reference by keeping the first and last frame and averaging the phase correlation in two directions. The single montage representation of the pan is color designed using the same color transform masking techniques as used for the foreground object.

FIG. 30 shows that the sequence of frames in the camera pan after the background mask color transforms the montage has been applied to each frame used to create the montage. The mask is applied where there is no pre-existing mask thus retaining the motion object mask and color transform information while applying the background information with appropriate offsets. Alternatively for depth projects, the left and right eye views of each frame may be shown as pairs, or in a separate window for each eye for example. Furthermore, the images may be displayed on a three-dimensional viewing display as well.

In FIG. 31, a selected sequence of frames in the pan for clarity after the color background/depth enhanced background masks have been automatically applied to the frames where there is no pre-existing masks.

Static and drifting camera shots: Objects which are not moving and changing in a film scene cut can be considered “background” objects, as opposed to moving “foreground” objects. If a camera is not moving throughout a sequence of frames, associated background objects appear to be static for the sequence duration, and can be masked and colorized only once for all associated frames. This is the “static camera” (or “static background”) case, as opposed to the moving (e.g. panning) camera case, which requires stitching tool described above to generate a background composite.

Cuts or frame sequences involving little or no camera motion provide the simplest case for generating frame-image background “composites” useful for cut background colorization. However, since even a “static” camera experiences slight vibrations for a variety of reasons, the static background composition tool cannot assume perfect pixel alignment from frame-to-frame, requiring an assessment of inter-frame shifts, accurate to 1 pixel, in order to optimally associated pixels between frames prior to adding their data contribution into the composite (an averaged value). The Static Background Composite tool provides this capability, generating all the data necessary to later colorize and extract background colorization information for each of the associated frames.

Moving foreground objects such as actors, etc., are masked leaving the background and stationary foreground objects unmasked. Wherever the masked moving object exposes the background or foreground the instance of background and foreground previously occluded is copied into the single image with priority and proper offsets to compensate for movement. The offset information is included in a text file associated with the single representation of the background so that the resulting mask information can be applied to each frame in the scene cut with proper mask offsets.

Background composite output data uses a greyscale TIFF image file (bkg.*.tif) that includes averaged input background pixel values lending itself to colorization/depth enhancement, and an associated background text data file required for background mask extraction after associated background mask/colorization data/depth enhancement components (bkg.*.msk, bkg.*.lut, . . . ) have been established. Background text data provides filename, mask-offset, and other frame-dimensioning information for each constituent (input) frame associated with the composite, with the following per line (per frame) format: Frame-filename frame-x-offset frame-y-offset frame-width frame-height frame-left-margin-x-max frame-right-margin-x-min. Each of these data fields are integers except for the first (frame-filename), which is a string.

Initialization: Initialization of the static background composition process involves initializing and acquiring the data necessary to create the composited background image-buffer and -data. This requires a loop over all constituent input image frames. Before any composite data initialization can occur, the composite input frames must be identified, loaded, and have all foreground objects identified/colorized (i.e. tagged with mask labels, for exclusion from composite). These steps are not part of the static background composition procedure, but occur prior to invoking the composite tool after browsing a database or directory tree, selecting and loading relevant input frames, painting/depth assigning the foreground objects.

Get Frame Shift: Adjacent frames' image background data in a static camera cut may exhibit small mutual vertical and horizontal offsets. Taking the first frame in the sequence as a baseline, all successive frames' background images are compared to the first frames', fitting line-wise and column-wise, to generate two histograms of “measured” horizontal and vertical offsets, from all measurable image-lines and -columns. The modes of these histograms provide the most frequent (and likely) assessed frame offsets, identified and stored in arrays DVx[iframe], DVy[iframe] per frame [iframe]. These offset arrays are generated in a loop over all input frames.

Get Maximum Frame Shift: While looping over input frames during initialization to generate the DVx[ ], DVy[ ] offset array data, the absolute maximum DVxMax, DVyMax values are found from the DVx[ ], DVy[ ] values. These are required when appropriately dimensioning the resultant background composite image to accommodate all composited frames' pixels without clipping.

Get Frame Margin: While looping over input frames during initialization, an additional procedure is invoked to find the right edge of the left image margin as well as the left edge of the right image margin. As pixels in the margins have zero or near-zero values, the column indexes to these edges are found by evaluating average image-column pixel values and their variations. The edge column-indexes are stored in arrays lMarg[iframe] and rMarg[iframe] per frame [iframe], respectively.

Extend Frame Shifts with Maximum: The Frame Shifts evaluated in the GetFrameShift( ) procedure described are relative to the “baseline” first frame of a composited frame sequence, whereas the sought frame shift values are shifts/offsets relative to the resultant background composite frame. The background composite frame's dimensions equal the first composite frame's dimensions extended by vertical and horizontal margins on all sides with widths DVxMax, DVyMax pixels, respectively. Frame offsets must therefore include margin widths relative to the resultant background frame, and therefore need to be added, per iframe, to the calculated offset from the first frame: DVx[iframe]=DVx[iframe]+DVxMax DVy[iframe]=DVy[iframe]+DVyMax

Initialize Composite Image: An image-buffer class object instance is created for the resultant background composite. The resultant background composite has the dimensions of the first input frame increased by 2*DVxMax (horizontally) and 2*DVyMax (vertically) pixels, respectively. The first input frame background image pixels (mask-less, non-foreground pixels) are copied into the background image buffer with the appropriate frame offset. Associated pixel composite count buffer values are initialized to one (1) for pixels receiving an initialization, zero (0) otherwise. See FIG. 38A for the flow of the processing for extracting a background, which occurs by generating a frame mask for all frames of a scene for example. FIG. 38B illustrations the determination of the amount of Frame shift and margin that is induced for example by a camera pan. The composite image is saved after determining and overlaying the shifted images from each of the desired frames for example.

FIG. 39A shows the edgeDetection and determination of points to snap to (1.1 and 1.2 respectively), which are detailed in FIGS. 39B and 39C respectively and which enable one skilled in the art to implement a image edge detection routine via Average Filter, Gradient Filter, Fill Gradient Image and a comparison with a Threshold. In addition, the GetSnapPoint routine of FIG. 39C shows the determination of a NewPoint based on the BestSnapPoint as determined by the RangeImage less than MinDistance as shown.

FIGS. 40A-C shows how a bimodal threshold tool is implemented in one or more embodiments of the invention. Creation of an image of light and dark cursor shape is implemented with the MakeLightShape routine wherein the light/dark values for the shape are applied with the respective routine as shown at the end of FIG. 40A. These routines are shown in FIGS. 40C and 40B respectively. FIGS. 41A-B show the calculation of FitValues and gradients for use in one or more of the above routines.

Composite Frame Loop: Input frames are composited (added) sequentially into the resultant background via a loop over the frames. Input frame background pixels are added into the background image buffer with the relevant offset (DVx[iframe], DVy[iframe]) for each frame, and associated pixel composite count values are incremented by one (1) for pixels receiving a composite addition (a separate composite count array/buffer is provided for this). Only background pixels, those without an associated input mask index, are composited (added) into the resultant background; pixels with nonzero (labeled) mask values are treated as foreground pixels and are therefore not subject to composition into the background; thus they are ignored. A status bar in the Gill is incremented per pass through the input frame loop.

Composite Finish: The final step in generating the output composite image buffer requires evaluating pixel averages which constitute the composite image. Upon completion of the composite frame loop, a background image pixel value represents the sum of all contributing aligned input frame pixels. Since resultant output pixels must be an average of these, division by a count of contributing input pixels is required. The count per pixel is provided by the associated pixel composite count buffer, as mentioned. All pixels with nonzero composite counts are averaged; other pixels remain zero.

Composite Image Save: A TIFF format output gray-scale image with 16 bits per pixel is generated from composite-averaged background image buffer. The output filename is composed from the first composite input frame filename by pre-pending the “bkg.” prefix (and appending the usual “.tif’ image extension if required), and writing to the associated background folder at path “../Bckgrnd Frm”, if available, otherwise to the default path (same as input frames').

Background Text Data Save: An output text data file containing parameter values relevant for background mask extraction as generated from the initialization phase described in (40A-C). As mentioned in the introduction (see FIG. 39A), each text data record consists of: Frame-filename frame-x-offset frame-y-offset frame-width frame-height frame-left-margin-x-max frame-right-margin-x-min.

The output text data filename is composed from the first composite input frame rootname by prepending the “bkg.” prefix and appending the “.txt” extension, and writing to the associated background folder at path “../Bckgrnd Frm”, if available, otherwise to the default path (same as input frames').

EXAMPLE

A complete output text data file called “bkg.02.00.06.02.txt”:

C:\NewYolder\Static_Backgrounding_Test\02.00.06.02.tif 1 4 1920 1080 0 1919

C:\New_Folder\Static_Backgrounding_Test\02.00.06.03.tif 1 4 1920 1080 0 1919

C:\New_Folder\Static_Backgrounding_Test\02.00.06.04.tif 1 3 1920 1080 0 1919

C:\New_Folder\Static_Backgrounding_Test\02.00.06.05.tif 2 3 1920 1080 0 1919

C:\New_Folder\Static_Backgrounding_Test\02.00.06.06.tif 1 3 1920 1080 0 1919

Data Cleanup: Releases memory allocated to data objects used by the static background composite procedure. These include the background composite GUI dialog object and its member arrays DVx[ ], DVy[ ], lMarg[ ], rMarg[ ], and the background composite image buffer object, whose contents have previously been saved to disk and are no longer needed.

Colorization/Depth Assignment of the Composite Background

Once the background is extracted as described above the single frame can be masked by an operator with.

The offset data for the background composite is transferred to the mask data overlaying the background such that the mask for each successive frame used to create the composite is placed appropriately.

The background mask data is applied to each successive frame wherever there are no pre-existing masks (e.g. the foreground actors).

FIG. 32 shows a sequence of frames in which all moving objects (actors) are masked with separate color transforms/depth enhancements.

FIG. 33 shows a sequence of selected frames for clarity prior to background mask information. All motion elements have been fully masked using the automatic mask-fitting algorithm.

FIG. 34 shows the stationary background and foreground information minus the previously masked moving objects. In this case, the single representation of the complete background has been masked with color transforms in a manner similar to the motion objects. Note that outlines of removed foreground objects appear truncated and unrecognizable due to their motion across the input frame sequence interval, i.e., the black objects in the frame represent areas in which the motion objects (actors in this case) never expose the background and foreground, i.e., missing background image data 3401. The black objects are ignored for colorization-only projects during the masking operation because the resulting background mask is later applied to all frames used to create the single representation of the background only where there is no pre-existing mask. For depth related projects, the black objects where missing background image data 3401 exists, may artistically or realistically rendered, for example to fill in information to be utilized in the conversion of two-dimensional images into three-dimensional images. Since these areas are areas where pixels may not be borrowed from other frames since they are never exposed in a scene, drawing them or otherwise creating believable images there, allows for all background information to be present and used for artifact free two-dimensional to three-dimensional conversion. For example, in order to create artifact-free three-dimensional image pairs from a two-dimensional image having areas that are never exposed in a scene, backgrounds having all or enough required information for the background areas that are always occluded may be generated. The missing background image data 3401 may be painted, drawn, created, computer-generated or otherwise obtained from a studio for example, so that there is enough information in a background, including the black areas to translate foreground objects horizontally and borrow generated background data for the translated edges for occluded areas. This enables the generation of artifact free three-dimensional image pairs since translation of foreground objects horizontally, which may expose areas that are always occluded in a scene, results in the use of the newly created background data instead of stretching objects or morphing pixels which creates artifacts that are human detectable errors. Hence, obtaining backgrounds with occluded areas filled in, either partially with enough horizontal realistic image data or fully with all occluded areas rendered into a realistic enough looking area, i.e., drawn and colorized and/or depth assigned, thus results in artifact free edges for depth enhanced frames. See also FIGS. 70 and 71-76 and the associated description respectively. Generation of missing background data may also be utilized to create artifact free edges along computer-generated elements as well.

FIG. 35 shows the sequential frames in the static camera scene cut after the background mask information has been applied to each frame with appropriate offsets and where there is no pre-existing mask information.

FIG. 36 shows a representative sample of frames from the static camera scene cut after the background information has been applied with appropriate offsets and where there is no pre-existing mask information.

Colorization Rendering: After color processing is completed for each scene, subsequent or sequential color motion masks and related lookup tables are combined within 24-bit or 48-bit RGB color space and rendered as TIF or TGA files. These uncompressed, high-resolution images are then rendered to various media such as HDTV, 35 mm negative film (via digital film scanner), or a variety of other standard and non standard video and film formats for viewing and exhibit.

Process Flow:

Digitization, Stabilization and Noise Reduction:

1. 35 mm film is digitized to 1920×1080×10 in any one of several digital formats.

2. Each frame undergoes standard stabilization techniques to minimize natural weaving motion inherent in film as it traverses camera sprockets as well as any appropriate digital telecine technology employed. Frame-differencing techniques are also employed to further stabilize image flow.

3. Each frame then undergoes noise reduction to minimize random film grain and electronic noise that may have entered into the capture process.

Pre-Production Movie Dissection Into Camera Elements and Visual Database Creation:

1. Each scene of the movie is broken down into background and foreground elements as well as movement objects using various subtraction, phase correlation and focal length estimation algorithms. Background and foreground elements may include computer-generated elements or elements that exist in the original movie footage for example.

2. Backgrounds and foreground elements m pans are combined into a single frame using uncompensated (lens) stitching routines.

3. Foregrounds are defined as any object and/or region that move in the same direction as the background but may represent a faster vector because of its proximity to the camera lens. In this method pans are reduced to a single representative image, which contains all of the background and foreground information taken from a plurality of frames.

4. Zooms are sometimes handled as a tiled database in which a matrix is applied to key frames where vector points of reference correspond to feature points in the image and correspond to feature points on the applied mask on the composited mask encompassing any distortion.

5. A database is created from the frames making up the single representative or composited frame (i.e., each common and novel pixel during a pan is assigned to the plurality of frames from which they were derived or which they have in common).

6. In this manner, a mask overlay representing an underlying lookup table will be correctly assigned to the respective novel and common pixel representations of backgrounds and foregrounds in corresponding frames.

Pre-Production Design Background Design:

1. Each entire background is colorized/depth assigned as a single frame in which all motion objects are removed. Background masking is accomplished using a routine that employs standard paint, fill, digital airbrushing, transparency, texture mapping, and similar tools. Color selection is accomplished using a 24-bit color lookup table automatically adjusted to match the density of the underlying gray scale and luminance. Depth assignment is accomplished via assigning depths, assigning geometric shapes, entry of numeric values with respect to objects, or in any other manner in the single composite frame. In this way creatively selected colors/depths are applied that are appropriate for mapping to the range of gray scale/depth underlying each mask. The standard color wheel used to select color ranges detects the underlying grayscale dynamic range and determines the corresponding color range from which the designer may choose (i.e., only from those color saturations that will match the grayscale luminance underlying the mask.)

2. Each lookup table allows for a multiplicity of colors applied to the range of gray scale values underlying the mask. The assigned colors will automatically adjust according to luminance and/or according to pre-selected color vectors compensating for changes in the underlying gray scale density and luminance.

Pre-Production Design Motion Element Design:

1. Design motion object frames are created which include the entire scene background as well as a single representative moment of movement within the scene in which all characters and elements within the scene are present. These moving non-background elements are called Design Frame Objects (DFO).

2. Each DFO is broken down into design regions of interest (regions of interest) with special attention focused on contrasting elements within the DFOs that can be readily be isolated using various gray scale and luminance analyses such as pattern recognition and or edge detection routines. As existing color movies may be utilized for depth enhancement, regions of interest may be picked with color taken into account.

3. The underlying gray scale- and luminance distribution of each masked region is displayed graphically as well as other gray scale analyses including pattern analysis together with a graphical representation of the region's shape with area, perimeter and various weighting parameters.

4. Color selection is determined for each region of interest comprising each object based on appropriate research into the film genre, period, creative intention, etc. and using a 24 bit color lookup table automatically adjusted to match the density of the underlying gray scale and luminance suitable and creatively selected colors are applied. The standard color wheel detects the underlying grayscale range and restricts the designer to choose only from those color saturations that will match the grayscale luminance underlying the mask. Depth assignments may be made or adjusted for depth projects until realistic depth is obtained for example.

5. This process continues until a reference design mask is created for all objects that move in the scene.

Pre-Production Design Key Frame Objects Assistant Designer:

1. Once all color selection/depth assignment is generally completed for a particular scene the design motion object frame is then used as a reference to create the larger number of key frame objects within the scene.

2. Key Frame Objects (all moving elements within the scene such as people, cars, etc that do not include background elements) are selected for masking.

3. The determining factor for each successive key frame object is the amount of new information between one key frame and the next key frame object.

Method of Colorizing/Depth Enhancing Motion Elements in Successive Frames:

1. The Production Colorist (operator) loads a plurality of frames into the display buffer.

2. One of the frames in the display buffer will include a key frame from which the operator obtains all masking information. The operator makes no creative or color/depth decisions since all color transform information is encoded within the key frame masks.

3. The operator can toggle from the colorized or applied lookup tables to translucent masks differentiated by arbitrary but highly contrasting colors.

4. The operator can view the motion of all frames in the display buffer observing the motion that occurs in successive frames or they can step through the motion from one key frame to the next.

5. The operator propagates (copies) the key frame mask information to all frames in the display buffer.

6. The operator then executes the mask fitting routine on each frame successively. FIG. 37A shows the mask fitting generally processing flow chart that is broken into subsequent detailed flow charts 37B and 37C. The program makes a best fit based on the grayscale/luminance, edge parameters and pattern recognition based on the gray scale and luminance pattern of the key frame or the previous frame in the display. For computer-generated elements, the mask fitting routines are skipped since the masks or alphas define digitally created (and hence non-operator-defined) edges that accurately define the computer-generated element boundaries. Mask fitting operations take into account the computer-generated element masks or alphas and stop when hitting the edge of a computer-generated element mask since these boundaries are accepted as accurate irrespective of grey-scale as per step 3710 of FIG. 37C. This enhances the accuracy of mask edges and reshapes when colors of a computer-generated element and operator-defined mask are of the same base luminance for example. As shown in FIG. 37A, the Mask Fit initializes the region and fit grid parameters, then calls the Calculate fit grid routine and then the Interpolate mask on fit grid routine, which execute on any computer as described herein, wherein the routines are specifically configured to calculate fit grids as specified in FIGS. 37B and 37C. The flow of processing of FIG. 37B from the Initialize region routine, to the initialization of image line and image column and reference image flows into the CalculateFitValue routine which calls the fit gradient routine which in turn calculates xx, and yy as the difference between the xfit, yfit and gradients for x and y. If the FitValue is greater than the fit, for x, y and xx and yy, then the xfit and yfit values are stored in the FitGrid. Otherwise, processing continues back at the fit gradient routine with new values for xfit and yfit. When the processing for the size of the Grid is complete for x and y, then the mask is interpolated as per FIG. 37C. After initialization, the indices i and j for the FitGridCell are determined and a bilinear interpolation is performed at the fitGridA-D locations wherein the Mask is fit up to any border found for any CG element at 3710 (i.e., for a known alpha border or border with depth values for example that define a digitally rendered element that is taken as a certified correct mask border). The mask fitting interpolation is continued up to the size of the mask defined by xend and vend.

7. In the event that movement creates large deviations in regions from one frame to the next the operator can select individual regions to mask-fit. The displaced region is moved to the approximate location of the region of interest where the program attempts to create a best fit. This routine continues for each region of interest in succession until all masked regions have been applied to motion objects in all sequential frames in the display memory.

a. The operator clicks on a single mask in each successive frame on the corresponding area where it belongs in frame 2. The computer makes a best fit based on the grayscale/luminance, edge parameters, gray scale pattern and other analysis.

b. This routine continues for each region in succession until all regions of interest have been repositioned in frame two.

c. The operator then indicates completion with a mouse click and masks in frame two are compared with gray scale parameters in frame three.

d. This operation continues until all motion in all frames between two or more key frames is completely masked.

8. Where there is an occlusion, a modified best-fit parameter is used. Once the occlusion is passed, the operator uses the pre-occlusion frame as a reference for the post occlusion frames.

9. After all motion is completed, the background/set mask is applied to each frame in succession. Application is: apply mask where no mask exists.

10. Masks for motion objects can also be animated using either Bezier curves or polygons that enclose a region of interest.

a. A plurality of frames are loaded into display memory and either Bezier points and curves of polygon points are applied close to the region of interest where the points automatically snap to edges detected within the image data.

b. Once the object in frame one has been enclosed by the polygon or Bezier curves the operator adjusts the polygon or Bezier in the last frame of the frames loaded in display memory.

c. The operator then executes a fitting routine, which snaps the polygons or Bezier points plus control curves to all intermediate frames, animating the mask over all frames in display memory.

d. The polygon and Bezier algorithms include control points for rotation, scaling and move-all to handle zooms, pans and complex camera moves where necessary.

FIG. 42 shows two image frames that are separated in time by several frames, of a person levitating a crystal ball wherein the various objects in the image frames are to be converted from two-dimensional objects to three-dimensional objects. As shown the crystal ball moves with respect to the first frame (shown on top) by the time that the second frame (shown on the bottom) occurs. As the frames are associated with one another, although separated in time, much of the masking information can be utilized for both frames, as reshaped using embodiments of the invention previously described above. For example, using the mask reshaping techniques described above for colorization, i.e., using the underlying grey-scale for tracking and reshaping masks, much of the labor involved with converting a two-dimensional movie to a three-dimensional movie is eliminated. This is due to the fact that once key frames have color or depth information applied to them, the mask information can be propagated automatically throughout a sequence of frames which eliminates the need to adjust wire frame models for example. Although there are only two images shown for brevity, these images are separated by several other images in time as the crystal ball slowly moves to the right in the sequence of images.

FIG. 43 shows the masking of the first object in the first image frame that is to be converted from a two-dimensional image to a three-dimensional image. In this figure, the first object masked is the crystal ball. There is no requirement to mask objects in any order. In this case a simple free form drawing tool is utilized to apply a somewhat round mask to the crystal ball. Alternatively, a circle mask may be dropped on the image and resized and translated to the correct position to correspond to the round crystal ball. However, since most objects masked are not simple geometric shapes, the alternative approach is shown herein. The grey-scale values of the masked object are thus utilized to reshape the mask in subsequent frames.

FIG. 44 shows the masking of the second object in the first image frame. In this figure, the hair and face of the person behind the crystal ball are masked as the second object using a free form drawing tool. Edge detection or grey-scale thresholds can be utilized to accurately set the edges of the masks as has been previously described above with respect to colorization. There is no requirement that an object be a single object, i.e., the hair and face of a person can be masked as a single item, or not and depth can thus be assigned to both or individually as desired.

FIG. 45 shows the two masks in color in the first image frame allowing for the portions associated with the masks to be viewed. This figure shows the masks as colored transparent masks so that the masks can be adjusted if desired.

FIG. 46 shows the masking of the third object in the first image frame. In this figure the hand is chosen as the third object. A free form tool is utilized to define the shape of the mask.

FIG. 47 shows the three masks in color in the first image frame allowing for the portions associated with the masks to be viewed. Again, the masks can be adjusted if desired based on the transparent masks.

FIG. 48 shows the masking of the fourth object in the first image frame. As shown the person's jacket form the fourth object.

FIG. 49 shows the masking of the fifth object in the first image frame. As shown the person's sleeve forms the fifth object.

FIG. 50 shows a control panel for the creation of three-dimensional images, including the association of layers and three-dimensional objects to masks within an image frame, specifically showing the creation of a Plane layer for the sleeve of the person in the image. On the right side of the screendump, the “Rotate” button is enabled, shown a “Translate Z” rotation quantity showing that the sleeve is rotated forward as is shown in the next figure.

FIG. 51 shows a three-dimensional view of the various masks shown in FIGS. 43-49, wherein the mask associated with the sleeve of the person is shown as a Plane layer that is rotated toward the left and right viewpoints on the right of the page. Also, as is shown the masks associated with the jacket and person's face have been assigned a Z-dimension or depth that is in front of the background.

FIG. 52 shows a slightly rotated view of FIG. 51. This figure shows the Plane layer with the rotated sleeve tilted toward the viewpoints. The crystal ball is shown as a flat object, still in two-dimensions as it has not yet been assigned a three-dimensional object type.

FIG. 53 shows a slightly rotated view of FIGS. 51 (and 52), wherein the sleeve is shown tilting forward, again without ever defining a wire frame model for the sleeve. Alternatively, a three-dimensional object type of column can be applied to the sleeve to make an even more realistically three-dimensional shaped object. The Plane type is shown here for brevity.

FIG. 54 shows a control panel specifically showing the creation of a sphere object for the crystal ball in front of the person in the image. In this figure, the Sphere three-dimensional object is created and dropped into the three-dimensional image by clicking the “create selected” button in the middle of the frame, which is then shown (after translation and resizing onto the crystal ball in the next figure).

FIG. 55 shows the application of the sphere object to the flat mask of the crystal ball, that is shown within the sphere and as projected to the front and back of the sphere to show the depth assigned to the crystal ball. The Sphere object can be translated, i.e., moved in three axis, and resized to fit the object that it is associated with. The projection of the crystal ball onto the sphere shows that the Sphere object is slightly larger than the crystal ball, however this ensures that the full crystal ball pixels are assigned depths. The Sphere object can be resized to the actual size of the sphere as well for more refined work projects as desired.

FIG. 56 shows a top view of the three-dimensional representation of the first image frame showing the Z-dimension assigned to the crystal ball shows that the crystal ball is in front of the person in the scene.

FIG. 57 shows that the sleeve plane rotating in the X-axis to make the sleeve appear to be coming out of the image more. The circle with a line (X axis line) projecting through it defines the plane of rotation of the three-dimensional object, here a plane associated with the sleeve mask.

FIG. 58 shows a control panel specifically showing the creation of a Head object for application to the person's face in the image, i.e., to give the person's face realistic depth without requiring a wire model for example. The Head object is created using the “Created Selected” button in the middle of the screen and is shown in the next figure.

FIG. 59 shows the Head object in the three-dimensional view, too large and not aligned with the actual person's head. After creating the Head object as per FIG. 58, the Head object shows up in the three-dimensional view as a generic depth primitive that is applicable to heads in general. This is due to the fact that depth information is not exactly required for the human eye. Hence, in depth assignments, generic depth primitives may be utilized in order to eliminate the need for three-dimensional wire frames. The Head object is translated, rotated and resized in subsequent figures as detailed below.

FIG. 60 shows the Head object in the three-dimensional view, resized to fit the person's face and aligned, e.g., translated to the position of the actual person's head.

FIG. 61 shows the Head object in the three-dimensional view, with the Y-axis rotation shown by the circle and Y-axis originating from the person's head thus allowing for the correct rotation of the Head object to correspond to the orientation of the person's face.

FIG. 62 shows the Head object also rotated slightly clockwise, about the Z-axis to correspond to the person's slightly tilted head. The mask shows that the face does not have to be exactly lined up for the result three-dimensional image to be believable to the human eye. More exacting rotation and resizing can be utilized where desired.

FIG. 63 shows the propagation of the masks into the second and final image frame. All of the methods previously disclosed above for moving masks and reshaping them are applied not only to colorization but to depth enhancement as well. Once the masks are propagated into another frame, all frames between the two frames may thus be tweened. By tweening the frames, the depth information (and color information if not a color movie) are thus applied to non-key frames.

FIG. 64 shows the original position of the mask corresponding to the person's hand.

FIG. 65 shows the reshaping of the mask, that is performed automatically and with can be adjusted in key frames manually if desired, wherein any intermediate frames get the tweened depth information between the first image frame masks and the second image frame masks. The automatic tracking of masks and reshaping of the masks allows for great savings in labor. Allowing manual refinement of the masks allows for precision work where desired.

FIG. 66 shows the missing information for the left viewpoint as highlighted in color on the left side of the masked objects in the lower image when the foreground object, here a crystal ball is translated to the right. In generating the left viewpoint of the three-dimensional image, the highlighted data must be generated to fill the missing information from that viewpoint.

FIG. 67 shows the missing information for the right viewpoint as highlighted in color on the right side of the masked objects in the lower image when the foreground object, here a crystal ball is translated to the left. In generating the right viewpoint of the three-dimensional image, the highlighted data must be generated to fill the missing information from that viewpoint. Alternatively, a single camera viewpoint may be offset from the viewpoint of the original camera, however the missing data is large for the new viewpoint. This may be utilized if there are a large number of frames and some of the missing information is found in adjacent frames for example.

FIG. 68 shows an anaglyph of the final depth enhanced first image frame viewable with Red/Blue 3-D glasses. The original two-dimensional image is now shown in three-dimensions.

FIG. 69 shows an anaglyph of the final depth enhanced second and last image frame viewable with Red/Blue 3-D glasses, note rotation of person's head, movement of person's hand and movement of crystal ball. The original two-dimensional image is now shown in three-dimensions as the masks have been moved/reshaped using the mask tracking/reshaping as described above and applying depth information to the masks in this subsequent frame from an image sequence. As described above, the operations for applying the depth parameter to a subsequent frame is performed using a general purpose computer having a central processing unit (CPU), memory, bus situated between the CPU and memory for example specifically programmed to do so wherein figures herein which show computer screen displays are meant to represent such a computer.

FIG. 70 shows the right side of the crystal ball with fill mode “smear”, wherein the pixels with missing information for the left viewpoint, i.e., on the right side of the crystal ball are taken from the right edge of the missing image pixels and “smeared” horizontally to cover the missing information. Any other method for introducing data into hidden areas is in keeping with the spirit of the invention. Stretching or smearing pixels where missing information is creates artifacts that are recognizable to human observers as errors. By obtaining or otherwise creating realistic data for the missing information is, i.e., for example via a generated background with missing information filled in, methods of filling missing data can be avoided and artifacts are thus eliminated. For example, providing a composite background or frame with all missing information designated in a way that an artist can use to create a plausible drawing or painting of a missing area is one method of obtaining missing information for use in two-dimensional to three-dimensional conversion projects.

FIG. 71 shows a mask or alpha plane for a given frame of a scene, for an actor's upper torso and head 7101, and transparent wings 7102. The mask may include opaque areas shown as black and transparent areas that are shown as grey areas. The alpha plane may be generated for example as an 8 bit grey-scale “OR” of all foreground masks. Any other method of generating a foreground mask having motion objects or foreground object related masks defined is in keeping with the spirit of the invention.

FIG. 72 shows an occluded area, i.e., missing background image data 7201 as a colored sub-area of the actor of FIG. 71 that never uncovers the underlying background, i.e., where missing information in the background for a scene or frame occurs. This area is the area of the background that is never exposed in any frame in a scene and hence cannot be borrowed from another frame. When for example generating a composite background, any background pixel not covered by a motion object mask or foreground mask can have a simple Boolean TRUE value, all other pixels are thus the occluded pixels as is also shown in FIG. 34.

FIG. 73 shows the occluded area of FIG. 72 with generated data 7201 a for missing background image data that is artistically drawn or otherwise rendered to generate a complete and realistic background for use in artifact free two-dimensional to three-dimensional conversion. See also FIG. 34 and the description thereof. As shown, FIG. 73 also has masks drawn on background objects, which are shown in colors that differ from the source image. This allows for colorization or colorization modifications for example as desired.

FIG. 73A shows the occluded area with missing background image data 7201 b partially drawn or otherwise rendered to generate just enough of a realistic looking background for use in artifact free two-dimensional to three-dimensional conversion. An artist in this example may draw narrower versions of the occluded areas, so that offsets to foreground objects would have enough realistic background to work with when projecting a second view, i.e., translating a foreground object horizontally which exposes occluded areas. In other words, the edges of the missing background image data area may be drawn horizontally inward by enough to allow for some of the generated data to be used, or all of the generated data to be used in generating a second viewpoint for a three-dimensional image set.

In one or more embodiments of the invention, a number of scenes from a movie may be generated for example by computer drawing by artists or sent to artists for completion of backgrounds. In one or more embodiments, a website may be created for artists to bid on background completion projects wherein the website is hosted on a computer system connected for example to the Internet. Any other method for obtaining backgrounds with enough information to render a two-dimensional frame into a three-dimensional pair of viewpoints is in keeping with the spirit of the invention, including rendering a full background with realistic data for all of the occluded area of FIG. 72 (which is shown in FIG. 73) or only a portion of the edges of the occluded area of FIG. 72, (which is shown as FIG. 73A). By estimating a background depth and a depth to a foreground object and knowing the offset distance desired for two viewpoints, it is thus possible to obtain less than the whole occluded area for use in artifact free two-dimensional to three-dimensional conversion. In one or more embodiments, a fixed offset, e.g., 100 pixels on each edge of each occluded area, or a percentage of the size of the foreground object, i.e., 5% for example, may flagged to be created and if more data is needed, then the frame is flagged for updating, or smearing or pixel stretching may be utilized to minimize the artifacts of missing data.

FIG. 74 shows a light area of the shoulder portion on the right side of FIG. 71, where missing background image data 7201 exists when generating a right viewpoint for a right image of a three-dimensional image pair. Missing background image data 7201 represents a gap where stretching (as is also shown in FIG. 70) or other artifact producing techniques would be used when shifting the foreground object to the left to create a right viewpoint. The dark portion of the figure is taken from the background where data is available in at least one frame of a scene.

FIG. 75 shows an example of the stretching of pixels, or “smeared pixels” 7201 c, corresponding to the light area in FIG. 74, i.e., missing background image data 7201, wherein the pixels are created without the use of a generated background, i.e., if no background data is available for an area that is occluded in all frames of a scene.

FIG. 76 shows a result of a right viewpoint without artifacts on the edge of the shoulder of the person through use of generated data 7201 a (or 7201 b) for missing background image data 7201 shown as for always-occluded areas of a scene.

FIG. 77 shows an example of a computer-generated element, here robot 7701, which is modeled in three-dimensional space and projected as a two-dimensional image. The background is grey to signify invisible areas. As is shown in the following figures, metadata such as alpha, mask, depth or any combination thereof is utilized to speed the conversion process from two-dimensional image to a pair of two-dimensional images for left and right eye for three-dimensional viewing. Masking this character by hand, or even in a computer-aided manner by an operator is extremely time consuming since there are literally hundreds if not thousands of sub-masks required to render depth (and/or color) correctly to this complex object.

FIG. 78 shows an original image separated into background 7801 and foreground elements 7802 and 7803, (mountain and sky in the background and soldiers in the bottom left also see FIG. 79) along with the imported color and depth of the computer-generated element, i.e., robot 7803 with depth automatically set via the imported depth metadata. Although the soldiers exist in the original image, their depths are set by an operator, and generally shapes or masks with varying depths are applied at these depths with respect to the original objects to obtain a pair of stereo images for left and right eye viewing. (See FIG. 79). As shown in the background, any area that is covered for the scene such as outline 7804 (of a soldier's head projected onto the background) can be artistically rendered for example to provide believable missing data, as is shown in FIG. 73 based on the missing data of FIG. 73A, which results in artifact free edges as shown in FIG. 76 for example. Importing data for computer generated elements may include reading a file that has depth information on a pixel-by-pixel basis for computer-generated element 7701 and displaying that information in a perspective view on a computer display as an imported element, e.g., robot 7803. This import process saves enormous amounts of operator time and makes conversion of a two-dimensional movie into a three-dimensional movie economically viable. One or more embodiments of the invention store the masks and imported data in computer memory and/or computer disk drives for use by one or more computers in the conversion process.

FIG. 79 shows mask 7901 (forming a portion of the helmet of the rightmost soldier) associated with the photograph of soldiers 7802 in the foreground. Mask 7901 along with all other operated-defined masks shown in multiple artificial colors on the soldiers, to apply depth to the various portions of the soldiers occurring in the original image that lie in depth in front of the computer-generated element, i.e., robot 7803. The dashed lines horizontally extending from the mask areas 7902 and 7903 show horizontal translation of the foreground objects takes place and where imported metadata can be utilized to accurately auto-correct over-painting of depth or color on the masked objects when metadata exists for the other elements of a movie. For example, when an alpha exists for the objects that occur in front of the computer-generated elements, the edges can be accurately determined. One type of file that can be utilized to obtain mask edge data is a file with alpha file and/or mask data such as an RGBA file. (See FIG. 80). In addition, use of generated data for missing areas of the background at these horizontally translated mask areas 7902 and 7903 enables artifact free two-dimensional to three-dimensional conversion.

FIG. 80 shows an imported alpha layer 8001 shown as a dark blue overlay, which can also be utilized as a mask layer to limit the operator defined, and potentially less accurate masks used for applying depth to the edges of the three soldiers 7802 and designated as soldiers A, B and C. In addition, an optional computer-generated element, such as dust can be inserted into the scene along the line annotated as “DUST”, to augment the reality of the scene if desired. Any of the background, foreground or computer-generated elements can be utilized to fill portions of the final left and right image pairs as is required.

FIG. 81 shows the result of using the operator-defined masks without adjustment when overlaying a motion element such as the soldier on the computer-generated element such as the robot. Without the use of metadata associated with the original image objects, such as matte or alpha 8001, artifacts occur where operator-defined masks do not exactly align with the edges of the masked objects. In the topmost picture, the soldier's lips show a light colored edge 8101 while the lower picture shows an artifact free edge since the alpha of FIG. 80 is used to limit the edges of any operator-defined masks. Through use of the alpha metadata of FIG. 80 applied to the operated-defined mask edges of FIG. 79, artifact free edges on the overlapping areas is thus enabled. As one skilled in the art will appreciate, application of successively nearer elements combined with their alphas is used to layer all of the objects at their various depths from back to front to create a final image pair for left eye and right eye viewing.

Embodiments of the invention enable real-time editing of 3D images without re-rendering for example to alter layers/colors/masks/depth or add or improve missing background information for example in gaps and/or remove artifacts in these elements and to minimize or eliminate iterative workflow paths back through different workgroups. Embodiments enable this functionality by locally altering masks, for example based on Z depth alpha mask manipulation, generating translation files, e.g., U Maps, that can be utilized as portable pixel-wise editing files, detecting gaps in the translations files for occluded areas and filling the gaps for example to make clean plates, or to more realistically fill the gap with blur and grain, or to add film grain based on luminance. In addition, depth may be manipulated by locally manipulating the U Maps or Z depth map or to otherwise displace regions in source files without re-rendering, e.g., without ray tracing and the huge computational effort involved with tracing light through each pixel in large format left and right eyes, through local shifting and manipulation of pixels which is several orders of magnitude faster. For example, a mask group takes source images and creates masks for items, areas or human recognizable objects in each frame of a sequence of images that make up a movie. The depth augmentation group applies depths, and for example shapes, to the masks created by the mask group. When rendering an image pair, left and right viewpoint images and left and right translation files and/or Z depth map may be generated by one or more embodiments of the invention. The left and right viewpoint images allow 3D viewing of the original 2D image. The translation files specify the pixel offsets for each source pixel in the original 2D image, for example in the form of UV or U maps. These files are generally related to an alpha mask for each layer, for example a layer for an actress, a layer for a door, a layer for a background, etc. These translation files, or maps are passed from the depth augmentation group that renders 3D images, to the quality assurance workgroup or composite group. This allows the quality assurance workgroup (or other workgroup such as the depth augmentation group) to perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks/depth or add or improve missing background information for example in gaps and/or remove artifacts such as masking errors without delays associated with processing time/re-rendering and/or iterative workflow that requires such re-rendering or sending the masks back to the mask group for rework, wherein the mask group may be in a third world country with unskilled labor on the other side of the globe. In addition, when rendering the left and right images, i.e., 3D images, the Z depth of regions within the image, such as actors for example, may also be passed along with the alpha mask to the quality assurance group, who may then adjust depth as well without re-rendering with the original rendering software. This may be performed for example with generated missing background data from any layer so as to allow “downstream” real-time editing without re-rendering or ray-tracing for example. Quality assurance may give feedback to the masking group or depth augmentation group for individuals so that these individuals may be instructed to produce work product as desired for the given project, without waiting for, or requiring the upstream groups to rework anything for the current project. This allows for feedback yet eliminates iterative delays involved with sending work product back for rework and the associated delay for waiting for the reworked work product. Elimination of iterations such as this provide a huge savings in wall-time, or end-to-end time that a conversion project takes, thereby increasing profits and minimizing the workforce needed to implement the workflow.

FIG. 82 shows a source image to be depth enhanced and provided along with left and right translation files (see FIGS. 85A-D and 86A-D for embodiments of translation files) and alpha masks (such as shown in FIG. 79) to enable real-time editing of 3D images without re-rendering or ray-tracing the entire image sequence in a scene (e.g., by downstream workgroups) for example to alter layers/colors/masks and/or remove and/or or adjust depths or otherwise change the 3D images without iterative workflow paths back to the original workgroups (as per FIG. 96 versus FIG. 95).

FIG. 83 shows masks generated by the mask workgroup for the application of depth by the depth augmentation group, wherein the masks are associated with objects, such as for example human recognizable objects in the source image of FIG. 82. Generally, unskilled labor is utilized to mask human recognizable objects in key frames within a scene or sequence of images. The unskilled labor is cheap and generally located offshore. Hundreds of workers may be hired at low prices to perform this tedious work associated with masking Any existing colorization masks may be utilized as a starting point for 3D masks, which may be combined to form a 3D mask outline that is broken into sub-masks that define differing depths within a human recognizable object. Any other method of obtaining masks for areas of an image are in keeping with the spirit of the invention.

FIG. 84 shows areas where depth is applied generally as darker for nearer objects and lighter for objects that are further away. This view gives a quick overview of the relative depths of objects in a frame.

FIG. 85A shows a left UV map containing translations or offsets in the horizontal direction for each source pixel. When rendering a scene with depths applied, translation maps that map the offsets of horizontal movement of individual pixels in a graphical manner may be utilized. FIG. 85B shows a right UV map containing translations or offsets in the horizontal direction for each source pixel. Since each of these images looks the same, it is easier to observe that there are subtle differences in the two files by shifting the black value of the color, so as to highlight the differences in a particular area of FIGS. 85A and 85B. FIG. 85C shows a black value shifted portion of the left UV map of FIG. 85A to show the subtle contents therein. This area corresponds to the tree branches shown in the upper right corner of FIGS. 82, 83 and 84 just above the cement mixer truck and to the left of the light pole. FIG. 85D shows a black value shifted portion of the right UV map of FIG. 85B to show the subtle contents therein. The branches shown in the slight variances of color signify that those pixels would be shifted to the corresponding location in a pure UV map that maps Red from darkest to lightest in the horizontal direction and maps Green from darkest to lightest in the vertical direction. In other words, the translation map in the UV embodiment is a graphical depiction of the shifting that occurs when generating a left and right viewpoint with respect to the original source image. UV maps may be utilized, however, any other file type that contains horizontal offsets from a source image on a pixel-by-pixel basis (or finer grained) may be utilized, including compressed formats that are not readily viewable as images. Some software packages for editing come with pre-built UV widgets, and hence, UV translation files or maps can therefore be utilized if desired. For example, certain compositing programs have pre-built objects that enable UV maps to be readily utilized and otherwise manipulated graphically and hence for these implementations, graphically viewable files may be utilized, but are not required.

Since creation of a left and right viewpoint from a 2D image uses horizontal shifts, it is possible to use a single color for the translation file. For example, since each row of the translation file is already indexed in a vertical direction based on the location in memory, it is possible to simply use one increasing color, for example Red in the horizontal direction to signify an original location of a pixel. Hence, any shift of pixels in the translation map are shown as shifts of a given pixel value from one horizontal offset to another, which makes for subtle color changes when the shifts are small, for example in the background. FIG. 86A shows a left U map containing translations or offsets in the horizontal direction for each source pixel. FIG. 86B shows a right U map containing translations or offsets in the horizontal direction for each source pixel. FIG. 86C shows a black value shifted portion of the left U map of FIG. 86A to show the subtle contents therein. FIG. 86D shows a black value shifted portion of the right U map of FIG. 86B to show the subtle contents therein. Again there is no requirement that a humanly viewable file format be utilized, and any format that stores horizontal offsets on a pixel-by-pixel basis relative to a source image may be utilized. Since memory and storage is so cheap, any format whether compressed or not may be utilized without any significant increase in cost however. Generally, creation of a right eye image makes foreground portions of the U map (or UV map) appear darker since they are shifting left and visa versa. This is easy to observe by looking at something in the foreground with only the right eye open and then moving slightly to the right (to observe that the foreground object has indeed been shifted to the left). Since the U map (or UV map) in the unaltered state is a simple ramp of color from dark to light, it then follows that shifting something to the left, i.e., for the right viewpoint, maps it to a darker area of the U map (or UV map). Hence the same tree branches in the same area of each U map (or UV map) are darker for the right eye and brighter for the left eye with respect to un-shifted pixels. Again, use of a viewable map is not required, but shows the concept of shifting that occurs for a given viewpoint.

FIG. 87 shows known uses for UV maps, wherein a three-dimensional model is unfolded so that an image in UV space can be painted onto the 3D model using the UV map. This figure shows how UV maps have traditionally been utilized to apply a texture map to a 3D shape. For example, the texture, here a painting or flat set of captured images of the Earth is mapped to a U and V coordinate system, that is translated to an X, Y and Z coordinate on the 3D model. Traditional animation has been performed in this manner in that wire frame models are unraveled and flattened, which defines the U and V coordinate system in which to apply a texture map.

Embodiments of the invention described herein utilize UV and U maps in a new manner in that a pair of maps are utilized to define the horizontal offsets for two images (left and right) that each source pixel is translated to as opposed to a single map that is utilized to define a coordinate onto which a texture map is placed on a 3D model or wire frame. I.e., embodiments of the invention utilize UV and U maps (or any other horizontal translation file format) to allow for adjustments to the offset objects without re-rendering the entire scene. Again, as opposed to the known use of a UV map, for example that maps two orthogonal coordinates to a three-dimensional object, embodiments of the invention enabled herein utilize two maps, i.e., one for a left and one for a right eye, that map horizontal translations for the left and right viewpoints. In other words, since pixels translate only in the horizontal direction (for left and right eyes), embodiments of the invention map within one-dimension on a horizontal line-by-line basis. I.e., the known art maps 2 dimensions to 3 dimensions, while embodiments of the invention utilize 2 maps of translations within 1 dimension (hence visible embodiments of the translation map can utilize one color). For example, if one line of a translation file contains 0, 1, 2, 3 . . . 1918, 1919, and the 2^(nd) and 3^(rd) pixels are translated right by 4 pixels, then the line of the file would read 0, 4, 5, 3 . . . 1918, 1919. Other formats showing relative offsets are not viewable as ramped color areas, but may provide great compression levels, for example a line of the file using relative offsets may read, 0, 0, 0, 0 . . . 0, 0, while a right shift of 4 pixels in the 2^(nd) and 3^(rd) pixels would make the file read 0, 4, 4, 0, . . . 0, 0. This type of file can be compressed to a great extent if there are large portions of background that have zero horizontal offsets in both the right and left viewpoints. However, this file could be viewed as a standard U file is it was ramped, i.e., made absolute as opposed to relative to view as a color-coded translation file. Any other format capable of storing offsets for horizontal shifts for left and right viewpoints may be utilized in embodiments of the invention. UV files similarly have a ramp function in the Y or vertical axis as well, the values in such a file would be (0,0), (0,1), (0,2) . . . (0, 1918), (0,1919) corresponding to each pixel, for example for the bottom row of the image and (1,0), (1,1), etc., for the second horizontal line, or row for example. This type of offset file allows for movement of pixels in non-horizontal rows, however embodiments of the invention simply shift data horizontally for left and right viewpoints, and so do not need the to keep track of which vertical row a source pixel moves to since horizontal movement is by definition within the same row.

FIG. 88 shows a disparity map showing the areas where the difference between the left and right translation maps is the largest. This shows that objects closest to the viewer have pixels that are shifted the most between the two UV (or U) maps shown in FIG. 85A-B (or 86A-B).

FIG. 89 shows a left eye rendering of the source image of FIG. 82. FIG. 90 shows a right eye rendering of the source image of FIG. 82. FIG. 91 shows an anaglyph of the images of FIG. 89 and FIG. 90 for use with Red/Blue glasses.

FIG. 92 shows an image that has been masked and is in the process of depth enhancement for the various layers, including the actress layer, door layer, background layer (showing missing background information that may be filled in through generation of missing information—see FIGS. 34, 73 and 76 for example). I.e., the empty portion of the background behind the actress in FIG. 92 can be filled with generated image data, (see the outline of the actress's head on the background wall). Through utilization of generated image data for each layer, a compositing program for example may be utilized as opposed to re-rendering or ray-tracing all images in a scene for real-time editing. For example, if the hair mask of the actress in FIG. 92 is altered to more correctly cover the hair, then any pixels uncovered by the new mask that are obtained from the background and are nearly instantaneous available to view (as opposed to standard re-rendering or ray-tracing that can take hours of processing power to re-render all of the images in a scene when anything in a scene is edited). This may include obtaining generated data for any layer including the background for use in artifact free 3D image generation.

FIG. 93 shows a UV map overlaid onto an alpha mask associated with the actress shown in FIG. 92 which sets the translation offsets in the resulting left and right UV maps based on the depth settings of the various pixels in the alpha mask. This UV layer may be utilized with other UV layers to provide a quality assurance workgroup (or other workgroup) with the ability to real-time edit the 3D images, for example to correct artifacts, or correct masking errors without re-rendering an entire image. Iterative workflows however may require sending the frame back to a third-world country for rework of the masks, which are then sent back to a different workgroup for example in the United States to re-render the image, which then viewed again by the quality assurance workgroup. This type of iterative workflow is eliminated or minor artifacts altogether since the quality assurance workgroup can simply reshape an alpha mask and regenerate the pixel offsets from the original source image to edit the 3D images in real-time and avoid involving other workgroups for example. Setting the depth of the actress as per FIGS. 42-70 for example or in any other method determines the amount of shift that the unaltered UV map undergoes to generate to UV maps, one for left-eye and one for right-eye image manipulation as per FIG. 85A-D, (or U maps in FIGS. 86A-D). The maps may be supplied for each layer along with an alpha mask for example to any compositing program, wherein changes to a mask for example allows the compositing program to simply obtain pixels from other layers to “add up” an image in real-time. This may include using generated image data for any layer (or gap fill data if no generated data exists for a deeper layer). One skilled in the art will appreciate that a set of layers with masks are combined in a compositing program to form an output image by arbitrating or otherwise determining which layers and corresponding images to lay on top of one another to form an output image. Any method of combining a source image pixel to form an output pixel using a pair of horizontal translation maps without re-rendering or ray-tracing again after adding depth is in keeping with the spirit of the invention.

FIG. 94 shows a workspace generated for a second depth enhancement program, based on the various layers shown in FIG. 92, i.e., left and right UV translation maps for each of the alphas wherein the workspace allows for quality assurance personnel (or other workgroups) to adjust masks and hence alter the 3D image pair (or anaglyph) in real-time without re-rendering or ray-tracking and/or without iteratively sending fixes to any other workgroup. One or more embodiments of the invention may loop through a source file for the number of layers and create script that generates the workspace as shown in FIG. 94. For example, once the mask workgroup has created the masks for the various layers and generated mask files, the rendering group may read in the mask files programmatically and generate script code that includes generation of a source icon, alpha copy icons for each layer, left and right UV maps for each layer based on the rendering groups rendered output, and other icons to combine the various layers into left and right viewpoint images. This allows the quality assurance workgroup to utilize tools that they are familiar with and which may be faster and less complex than the rendering tools utilized by the rendering workgroup. Any method for generation of a graphical user interface for a worker to enable real-time editing of 3D images including a method to create a source icon for each frame, that connects to an alpha mask icon for each layer and generates translation maps for left and right viewpoints that connect to one another and loops for each layer until combining with an output viewpoint for 3D viewing is in keeping with the spirit of the invention. Alternatively, any other method that enables real-time editing of images without re-rendering through use of a pair of translation maps is in keeping with the spirit of the invention even if the translation maps are not viewable or not shown to the user.

FIG. 95 shows a workflow for iterative corrective workflow. A mask workgroup generates masks for objects, such as for example, human recognizable objects or any other shapes in an image sequence at 9501. This may include generation of groups of sub-masks and the generation of layers that define different depth regions. This step is generally performed by unskilled and/or low wage labor, generally in a country with very low labor costs. The masked objects are viewed by higher skilled employees, generally artists, who apply depth and/or color to the masked regions in a scene at 9502. The artists are generally located in an industrialized country with higher labor costs. Another workgroup, generally a quality assurance group then views the resulting images at 9503 and determines if there are any artifacts or errors that need fixing based on the requirements of the particular project. If so, the masks with errors or locations in the image where errors are found are sent back to the masking workgroup for rework, i.e., from 9504 to 9501. Once there are no more errors, the process completes at 9505. Even in smaller workgroups, errors may be corrected by re-reworking masks and re-rendering or otherwise ray-tracing all of the images in a scene which can take hours of processing time to make a simple change for example. Errors in depth judgment generally occur less often as the higher skilled laborers apply depths based on a higher skill level, and hence kickbacks to the rendering group occur less often in general, hence this loop is not shown in the figure for brevity although this iterative path may occur. Masking “kickback” may take a great amount of time to work back through the system since the work product must be re-masked and then re-rendered by other workgroups.

FIG. 96 shows an embodiment of the workflow enabled by one or more embodiments of the system in that each workgroup can perform real-time editing of 3D images without re-rendering for example to alter layers/colors/masks and/or remove artifacts and otherwise correct work product from another workgroup without iterative delays associated with re-rendering/ray-tracing or sending work product back through the workflow for corrections. The generation of masks occurs as in FIG. 95 at 9501, depth is applied as occurs in FIG. 95 at 9502. In addition, the rendering group generates translation maps that accompany the rendered images to the quality assurance group at 9601. The quality assurance group views the work product at 9503 as in FIG. 95 and also checks for artifacts as in FIG. 95 at 9504. However, since the quality assurance workgroup (or other workgroup) has translation maps, and the accompanying layers and alpha masks, they can edit 3D images in real-time or otherwise locally correct images without re-rendering at 9602, for example using commercially available compositing programs such as NUKE® as one skilled in the art will appreciate. For instance as is shown in FIG. 94, the quality assurance workgroup can open a graphics program that they are familiar with (as opposed to a complex rendering program used by the artists), and adjust an alpha mask for example wherein the offsets in each left right translation map are reshaped as desired by the quality assurance workgroup and the output images are formed layer by layer (using any generated missing background information as per FIGS. 34, 73 and 76 and any computer generated element layers as per FIG. 79). As one skilled in the art will recognize, generating two output images from furthest back layer to foreground layer can be done without ray-tracing, by only overlaying pixels from each layer onto the final output images nearly instantaneously. This effectively allows for local pixel-by-pixel image manipulation by the quality assurance workgroup instead of 3D modeling and ray-tracing, etc., as utilized by the rendering workgroup. This can save multiple hours of processing time and/or delays associated with waiting for other workers to re-render a sequence of images that make up a scene.

FIG. 97 shows an embodiment of the rapid workflow for local modification of masks, gaps next to masks, depth maps, translation values such as UV or U Maps or any combination thereof to remove artifacts, create missing background information or otherwise adjust, alter, improve or otherwise modify rendered images without re-rendering or otherwise re-ray tracing the images. This saves a large amount of computing time since rendering/ray tracing is computationally expensive. In addition, this saves a tremendous amount of wall time since the masking process and rendering processes may be done by different sets of employees, for example distally located. Source images, for example an image sequence or frame of images in a scene are obtained at 9701, wherein masks associated with various objects or items in the images are also obtained. Depth maps, translation maps or values and optionally colors for the masked regions for the images are obtained at 9702. The rendered right and left images are obtained at 9703 and result from ray tracing source images using the depths associated with the masks with respect to two virtual cameras focused on a convergence point wherein the two virtual cameras offset horizontally by an intraocular or interaxial distance. The ray tracing process generates two images for each input source image, wherein the two images are intended for left and right eye viewing to produce highly realistic stereoscopic images for three-dimensional viewing, i.e., provide a stereoscopic 3D effect. Ray tracing enables optical effects such as refraction, reflection, dispersion and scattering for example but requires tracing each path of light through potentially numerous reflections and through translucent matter for each pixel in large format left and right eye images. Thus ray tracing in one or more embodiments of the invention is done once, wherein subsequent editing is done by local manipulation or shifting of pixels that is several orders of magnitude faster as per step 9706. The resulting left and right images may be combined into one image that may be viewed with polarized lenses or red/cyan lenses in the case of a polarized or an anaglyph image respectively through superposition of two images that are coded through polarity or color for example. Regardless of the output format of the right and left viewpoints, the ray tracing is computationally expensive and thus embodiments of the invention may entirely eliminate iterative ray tracing when masks, background missing information, gap fills, depths or any other value changes that would require re-rendering, i.e., ray tracing another time. The rendered images, for example created with ray tracing are displayed at 9704 and thus viewed with appropriate three-dimensional viewing apparatus by a quality assurance worker or compositing worker for example. If artifacts are detected at 9705, then embodiments of the invention at 9706 are utilized to locally modify masks, or depth maps, or translation maps or values, or any combination thereof without re-rendering or otherwise ray tracing the images/masks again. This step is performed generally until the results are satisfactory, or up to a quality assurance level that is acceptable or until otherwise desired, for example until the artifacts are no longer visible or objected to when the image sequence is viewed. If no artifacts are detected or not of a nature that warrants modification, as decided at 9705, or if local modification is complete at 9706, then processing completes at 9707.

In one or more embodiments of the invention gap analysis processing may be utilized to display color coding of gaps or other artifacts for example based on their magnitude or thickness to enable rapid identification and local modification of areas where artifacts may be visible or unacceptable. This is described below with further detail with respect to FIG. 103.

In one or more embodiments of the invention, the local modification of masks, depth maps, translation maps or masks or missing background information as performed at 9706 may include processing for Z Depth Alpha, UV Gap Detection, Gap Fill, Gap Blur Grain, Grain Merge, UV Distort, Z Distort or Displacer processing as enabled below.

Z Depth Alpha processing is shown in FIGS. 98A-D. Z Depth processing enables rapid workflow for 2D to 3D image conversion, and specifically enables dilation of edges of foreground masks to generate clean edges on foreground objects without re-rendering pairs of images. The depth mask shown in FIG. 98A includes masks for a man on the left facing away and a portion of a woman on the right facing towards the camera. As shown, the darker the pixel, the closer the pixel is and the lighter the pixel, the further away it is from the camera. This relationship may be inverted or encoded in any other manner so long as the depth map includes distance away from a camera, or cameras in the case of stereoscopic projection. The depth map may be encoded and not visual in nature if desired. By slicing the depth map, through for example accepting a cut off value of depth, so that any values greater than a threshold distance away from the camera are eliminated, the depth map of FIG. 98B is created. This eliminates the depths associated with any objects further in Z depth than the man for example. By accepting a fill amount, which controls the amount of expansion of the mask, the mask is effectively reshaped to create a modified depth mask. This may be utilized for example to refine the specific area where depth is applied to the source image, which enables one or more embodiments of the invention to update the left and right viewpoint images without ray tracing the entire image again. Thus, by enabling masks with three-dimensional information to be locally altered and new left and right viewpoint images to be updated, vast amounts of time may be saved when compared to sending the updated masks to a different workgroup for re-rendering for example.

UV Gap Detection processing is shown in FIGS. 99A-D. Specifically, this process takes input UV or U maps and looks for values that are the same horizontally within a threshold. Gaps are thus detected when the values are above threshold, i.e., have shifted enough to produce at least one pixel worth of missing background information. An output alpha is produced after analyzing the pixel-by-pixel horizontal offsets, or U values in ramp function that are shifted for example left and right. The initial pass through the U Map is shown in FIG. 99A. By increasing the threshold or tolerance, the narrower gaps are shown in FIG. 99B. The gaps may be blurred and clamped to remove gaps under a particular width or threshold and this is shown in FIG. 99C. The resulting gaps may be dilated to widen them as is shown in FIG. 99D. This produces the more important gaps in the form of an alpha mask in one or more embodiments of the invention. Any generated missing background information, or gap fill image data may be utilized in the gaps shown at the white lines in the alpha as desired. The gap may be displayed with different colors that represent the size of the gap so that the artist can concentrate on more obvious gaps for example, and as is shown in FIG. 103 which is described below.

Gap Fill processing is shown in FIGS. 100A-E and is utilized to extend the edge pixels of a masked area inward or outward. This process may be utilized to generate missing background information, expand depth masks, for example to extend edges of masked areas out when they are lost due to motion blur, or to otherwise restore motion blur or to account for other focus effects. In one or more embodiments, the input source image is masked with an alpha mask of a foreground object in the generation of missing background information. For example, in one embodiment, the alpha of the foreground object is utilized to mask out the foreground object, i.e., the woman's face shown in FIG. 100A. The alpha of the woman's face is utilized to mask the background as is shown in FIG. 100B. When the foreground object, i.e., the woman has depth applied, the mask associated with the image where the mask is located is shift left and right depending on how near or far away the masked area is set to reside at. In order to generate data to use when shifting the foreground object, generated missing background information is created for later depth use. See also FIGS. 71-76. The alpha is then eroded into the missing background information area at FIG. 100C to generate data around the masked foreground object for use when the foreground object is shifted left and right in applying foreground depth. If there are primarily vertical lines in the background near the masked foreground object as is shown in FIG. 100D, then the bias of the pixels, or stretching or extending of colors across the gap, is vertically. If there are primarily horizontal lines in the background near the masked foreground object, then the bias of the pixels, or stretching or extending of colors across the gap is horizontal. The missing background information may be blurred and grain from the film near the mask may also be added to the eroded area. Once the missing background information is generated, the foreground object may be depth adjusted to update previously rendered images without re-rendering the images. Any technique that can determine whether there are primarily horizontal or vertical or any other direction of lines in a background, including histogramming for example or FFT's may be utilized to determine whether to apply a background of a particular orientation as is shown in FIG. 100E.

Gap Blur Grain processing is shown in FIGS. 101A-E. As shown, in this example the gaps are detected in any manner as previously described or in any other manner as is shown in FIG. 101A. Once the gaps are identified, the gaps may be filled horizontally or vertically and also may be blurred with added film grain from near the gap. As is shown in FIG. 101B, if there is no apparent vertical or horizontal background, then either bias may be utilized, for example horizontal as is shown by extending the colors across the gaps in a horizontal manner, optionally blurred. As is shown in FIG. 101C, the film grain from an area outside of the gap for example at background depth may be utilized to randomize or otherwise make the horizontal or vertical gap fills more like the film grain in the background. Close ups of the gaps filled without film grain and with film grain are shown in FIGS. 101D and 101E respectively. In one or more embodiments of the invention, a pattern next to a gap may be automatically or manually sampled for variance wherein the difference between each color and a desired gap fill color is varied by the same pattern or amount. Any other method of providing a pattern that simulates the film grain in an image is in keeping with the spirit of the invention so long as the processing is local and not ray traced a second time. In addition, randomized grain in a known pattern may be based on, or a function of the underlying luminance as per FIGS. 102A-B.

Grain Merge processing is shown in FIGS. 102A-B. The upper area of each figure shows film grain as a function of the luminance, which increases from left to right. The bottom input area may be utilized to accept user inputs to change the mapping of film grain as luminance varies. As shown in FIG. 102A, film grain input to the gap fill processes may be set to not depend on the luminance. FIG. 102B however shows that more film grain is utilized in a low range of luminance, while no film grain is utilized in a luminance range just over half way across the luminance range. Thus, film grain or any type of noise may be set to vary as a function of luminance in any gap fill process or other process described herein.

UV Distort processing is performed by altering any of the UV or U maps 85A-D or 86A-D and then updating the left and right viewpoint images locally in order to avoid or eliminate ray tracing or re-rendering. In one embodiment, the pixels are simply moved to the new locations mapped by the UV or U maps to entirely avoid ray tracing.

Z Distort or Displacer processes utilize a depth map, for example as shown in FIG. 84 and alter the gray scale value, i.e., the depth of a particular element, and shift pixels left and right by the new amount to update the left and right viewpoint images without computationally intensive ray tracing processing, potentially by other workers using distal computers, which may be distal to any computers used by a second set of masking workers for example. In addition to the advantages of translation map alteration with UV or U maps, Z Distort also enables stereo camera adjustments in real-time and quick adjustments to depth in real-time, again without re-rendering the entire image for example via ray tracing. This enables depth occlusion by operating on nearer pixels last in one or more embodiments in combination with any of the gap fill techniques previously described. Displacer processing is a quick translation tool that enables left and right translation of pixels for modifying depth locally and in a quick manner that does not perform occlusion processing and gap fill. This enables quick adjustments to be viewed extremely quickly. In one or more embodiments of the invention, the convergence distance, and intraocular distance are obtained on a per image or per scene basis, for example obtained via metadata written in each image if desired. The source image and the depth map are altered by the user and obtained to remap depth values on a pixel basis without ray tracing. The pixels are shifted for left and right eyes based on the new depths with priority to foreground pixels so that they occlude background pixels. Wherever gaps are opened, generated missing background information or gap fill is then utilized to fill the gap. With respect to the pair of UV or U maps per image, Z maps or depth maps are easier to compress, and only utilize one map per source image. Less precision is generally utilized to store the data and small changes to depth can easily be made by compositors, for example locally in real-time without ray tracing the entire frame. In addition, other advantages include use of client provided depth maps and faster processing of operations on depth since only one map per image is altered. This processing enables easy correction of complex situations involving semi-transparent layers locally in real-time without ray tracing. Hence, local updating of image pairs is enabled through manipulation of local Z or depth maps and/or translation maps or values without the need for re-rendering through ray tracing.

In one or more embodiments of the invention gap analysis processing may be utilized to display color coding of gaps 10301, 10302, 10303 or other artifacts for example based on their magnitude or thickness to enable rapid identification and local modification of areas where artifacts may be visible or unacceptable. In one or more embodiments, the gap analysis processing draws Red areas 10301 for example in gaps that are thicker and will likely need more attention than narrower gaps that may for example be drawn as green areas 10302. Color coding artifacts or gaps also provides artists with an easily identifiable view of areas of an image where internal portions of characters/objects are broken, e.g., where regions are not aligned with their neighbors correctly. In one or more embodiments, a color lookup table may be utilized to provide a color for a given width gap. In other embodiments the gap value may compared with a threshold, for example with three ranges, 0-4, 5-9, 10+, wherein Green, Yellow and Red are applied to the gap based on the gap value.

While the invention herein disclosed has been described by means of specific embodiments and applications thereof, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope of the invention set forth in the claims. 

What is claimed is:
 1. A system configured to modify a set of time ordered digital images comprising at least one computer configured to: obtain a source image and at least one mask associated with a region in said source image; obtain a depth map or translation values associated with said at least one mask of said source image; obtain a render of a left viewpoint image of said source image created with ray tracing to a left virtual camera; obtain a render of a right viewpoint image of said source image created with ray tracing to a right virtual camera; modify said at least one mask or an area next to said at least one mask where missing background information is located or said depth map or said translation values or any combination thereof to create at least one modified mask or modified missing background information or modified depth map or modified translation values or any combination thereof; and, update said left viewpoint image and said right viewpoint image based on said at least one modified mask or said modified depth map or said modified translation values or said any combination thereof without another said ray tracing to said left virtual camera and without said ray tracing to said right virtual camera.
 2. The system of claim 1 wherein said depth map comprises depth information related to said at least one mask and wherein said depth map is sliced to exclude areas further than a threshold and wherein said at least one mask is reshaped to create said at least one modified depth mask.
 3. The system of claim 1 wherein said depth map comprises a distance away from a pair of virtual cameras.
 4. The system of claim 1 wherein said translation values comprise a left translation map and a right translation map that each contain pixel-by-pixel horizontal offsets of each pixel in said source image to said respective pixel in said left viewpoint image and said right viewpoint image respectively.
 5. The system of claim 1 wherein said left translation map and said right translation map are UV maps or U maps.
 6. The system of claim 1 wherein said at least one mask is created on a computer that is located distally to said at least one computer configured to update said left and right viewpoint images.
 7. The system of claim 1 wherein said depth map or said translation values are created on a computer that is located distally to said at least one computer configured to update said left and right viewpoint images.
 8. The system of claim 7 wherein said at least one computer configured to render said left viewpoint image and said right viewpoint image is configured to be controlled by a second laborer.
 9. The system of claim 1 wherein said update or said render or said update and said render of said left and right viewpoint images utilizes computer generated elements.
 10. The system of claim 1 wherein said update of said left and right viewpoint images utilizes generated missing background information for at least one portion of said source image that does not expose at least one area of another layer.
 11. The system of claim 1 wherein said update of said left and right viewpoint images utilizes generated missing background information or gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said generated missing background information or said gap fill data is applied to areas detected in said translation values that indicate an over threshold left or right shift of image data and wherein said areas are optionally blurred, optionally clamped and optionally dilated.
 12. The system of claim 1 wherein said update of said left and right viewpoint images utilizes gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said gap fill data comprises data that matches horizontal or vertical data near said missing background information in said source image.
 13. The system of claim 1 wherein said update of said left and right viewpoint images utilizes gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said gap fill data comprises blurred data from said source image.
 14. The system of claim 1 wherein update of said left and right viewpoint images utilizes gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said gap fill data comprises film grain from a region of said source image.
 15. The system of claim 1 wherein said update of said left and right viewpoint images utilizes gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said gap fill data comprises blurred data from said source image and film grain from a region of said source image.
 16. The system of claim 1 wherein said update of said left and right viewpoint images utilizes gap fill data for at least one portion of said source image that does not expose at least one area of another layer wherein said gap fill data comprises film grain from a region of said source image that is applied as a function of underlying luminance.
 17. The system of claim 1 wherein said update of said left and right viewpoint images utilizes modified translation values that are created by alteration of at least one translation value in a UV map or U map.
 18. The system of claim 1 wherein said update of said left and right viewpoint images utilizes a modified depth map that is created by alteration of at least one depth value in said depth map.
 19. The system of claim 1 wherein said update of said left and right viewpoint images utilizes a modified depth map that is created through displacement of pixels associated with said at least one mask left and right respectively by a numerical value shift in said depth map.
 20. The system of claim 1 wherein said computer is further configured to display a gap with a color based on a function of the size of said gap. 